Diagnosis, prognosis and identification of potential therapeutic targets of multiple myeloma based on gene expression profiling

ABSTRACT

Provided herein is a method for gene expression profiling multiple myeloma patients into distinct subgroups via DNA hybridization and hierarchical clustering analysis of the hybridization data where the results may further be used to identify therapeutic gene targets. Also provided is a method for controlling bone loss in an individual via pharmacological inhibitors of DKK1 protein. In addition provided herein is a method for diagnosing multiple myeloma using a 15-gene model that classifies myeloma into subtypes 1-7.

CROSS-REFERENCE TO RELATED APPLICATION

This is a divisional application of pending U.S. Ser. No. 12/012,302, filed Feb. 1, 2008, which is a divisional of U.S. Ser. No. 10/931,780, filed Sep. 1, 2004, now U.S. Pat. No. 7,371,736, which is a continuation-in-part of U.S. Ser. No. 10/454,263, filed Jun. 4, 2003, now U.S. Pat. No. 7,308,364, which is a continuation-in-part application of U.S. Ser. No. 10/409,004, filed Apr. 8, 2003, now U.S. Pat. No. 7,894,992, which is a continuation-in-part of U.S. Ser. No. 10/289,746, filed Nov. 7, 2002, now U.S. Pat. No. 6,668,659, which claims benefit of provisionals U.S. Ser. No. 60/403,075, filed Aug. 13, 2002, now abandoned, U.S. Ser. No. 60/355,386, filed Feb. 8, 2002, now abandoned, and U.S. Ser. No. 60/348,238, filed Nov. 7, 2001, now abandoned, the entirety of all of which are hereby incorporated by reference.

FEDERAL FUNDING LEGEND

This invention was made with government support under Grant Numbers NIH CA097513 and CA055819 awarded by the National Institutes of Health. The government has certain rights in the invention.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to the field of cancer research. More specifically, the present invention relates to gene expression profiling of cancer patient.

2. Description of the Related Art

Multiple myeloma (MM) is a uniformly fatal tumor of terminally differentiated plasma cells (PCs) that home to and expand in the bone marrow. Although initial transformation events leading to the development of multiple myeloma are thought to occur at a post-germinal center stage of development as suggested by the presence of somatic hypermutation of IGV genes, progress in understanding the biology and genetics of multiple myeloma has been slow.

Multiple myeloma cells are endowed with a multiplicity of anti-apoptotic signaling mechanisms that account for their resistance to current chemotherapy and thus the ultimately fatal outcome for most patients. While aneuploidy by interphase fluorescence in situ hybridization (FISH) and DNA flow cytometry are observed in >90% of cases, cytogenetic abnormalities in this typically hypoproliferative tumor are informative in only about 30% of cases and are typically complex, involving on average 7 different chromosomes. Given this “genetic chaos” it has been difficult to establish correlations between genetic abnormalities and clinical outcomes. Only recently has chromosome 13 deletion been identified as a distinct clinical entity with a grave prognosis. However, even with the most comprehensive analysis of laboratory parameters, such as b2-microglobulin (b2M), C-reactive protein (CRP), plasma cell labeling index (PCLI), metaphase karyotyping, and FISH, the clinical course of patients afflicted with multiple myeloma can only be approximated because no more than 20% of clinical heterogeneity can be accounted for. Thus, there are distinct clinical subgroups of multiple myeloma, and modern molecular tests may provide help in identifying these entities.

Monoclonal gammopathy of undetermined significance (MGUS) and multiple myeloma are the most frequent forms of monoclonal gammopathies. Monoclonal gammopathy of undetermined significance is the most common plasma cell dyscrasia with an incidence of up to 10% of population over age 75. The molecular basis of monoclonal gammopathy of undetermined significance and multiple myeloma are not very well understood and it is not easy to differentiate these two disorders. Diagnosis of multiple myeloma or monoclonal gammopathy of undetermined significance is identical in ⅔ of cases using classification systems that are based on a combination of clinical criteria such as the amount of bone marrow plasmocytosis, the concentration of monoclonal immunoglobulin in urine or serum, and the presence of bone lesions. Especially in early phases of multiple myeloma, differential diagnosis is associated with a certain degree of uncertainty.

Furthermore, in the diagnosis of multiple myeloma, clinician must exclude other disorders in which a plasma cell reaction may occur. These other disorders include rheumatoid arthritis, connective tissue disorders, and metastatic carcinoma where the patient may have osteolytic lesions associated with bone metastases. Therefore, given that multiple myeloma is thought to have an extended latency and clinical features are recognized many years after development of the malignancy, new molecular diagnostic techniques are needed for differential diagnosis of multiple myeloma, e.g., monoclonal gammopathy of undetermined significance versus multiple myeloma, or recognition of various subtypes of multiple myeloma.

Thus, the prior art is deficient in methods of differential diagnosing and identifying distinct and prognostically relevant clinical subgroups of multiple myeloma. The present invention fulfills this long-standing need and desire in the art.

SUMMARY OF THE INVENTION

Bone marrow plasma cells from 74 patients with newly diagnosed multiple myeloma, 5 patients with monoclonal gammopathy of undetermined significance (MGUS), and 31 normal volunteers (normal plasma cells) were purified by CD138⁺ selection. Gene expression of purified plasma cells and 7 multiple myeloma cell lines were profiled using high-density oligonucleotide microarrays interrogating ˜6,800 genes. Using hierarchical clustering analysis, normal and multiple myeloma plasma cells were differentiated and four distinct subgroups of multiple myeloma (MM1, MM2, MM3 and MM4) were identified. The gene expression patterns of MM1 was similar to that of normal plasma cells and monoclonal gammopathy of undetermined significance, whereas MM4 was similar to multiple myeloma cell lines. Clinical parameters linked to poor prognosis such as abnormal karyotype (p=0.0003) and high serum b2-microglobulin levels (p=0.0004) were most prevalent in MM4. Genes involved in DNA metabolism and cell cycle control were overexpressed in MM4 as compared to MM1.

Using chi square and Wilcoxon rank sum tests, 120 novel candidate disease genes that discriminated between normal and malignant plasma cells (p<0.0001) were identified. Many of these candidate genes are involved in adhesion, apoptosis, cell cycle, drug resistance, growth arrest, oncogenesis, signaling and transcription. In addition, a total of 156 genes, including FGFR3 and CCND1, exhibited highly elevated (“spiked”) expression in at least 4 of the 74 multiple myeloma cases (range of spikes: 4 to 25). Elevated expression of FGFR3 and CCND1 were caused by translocation t(4;14)(p16;q32) or t(11;14)(q13;q32).

The present invention also identifies, through multivariate stepwise discriminant analysis, a minimum subset of genes whose expression is intimately associated with malignant features of multiple myeloma. Fourteen genes were defined as predictors that are able to differentiate plasma cells of multiple myeloma patients from normal plasma cells with a high degree of accuracy, and 24 genes were identified as predictors that are able to differentiate distinct subgroups of multiple myeloma (MM1, MM2, MM3 and MM4) described herein.

Furthermore, data disclosed herein indicate that multiple myeloma can be placed into a developmental schema parallel to that of normal plasma cell differentiation. Based on gene expression profiling, the MM4, MM3 and MM2 subgroups described above were found to have similarity with tonsil B cells, tonsil plasma cells and bone marrow plasma cells respectively. These data suggest that the enigmatic multiple myeloma is amendable to a gene expression/development stage-based classification system.

The present invention demonstrates gene expression profiling using DNA microarray and hierarchical clustering analysis can be used to classify subgroups of multiple myeloma, identify genes with differential expression in subsets of multiple myeloma patients, and identify potential therapeutic targets for multiple myeloma. For example, there are provided methods of diagnosis for multiple myeloma or subgroups of multiple myeloma based on the expression of a group of 14 genes or a group of 24 genes respectively. There is also provided a method of multiple myeloma diagnosis based on the expression levels of 15 genes that classify patients into 7 subgroups of myeloma.

In another aspect of the present invention, there are provided methods of treatment for multiple myeloma. Such methods involve inhibiting or enhancing expression of genes that are found to be over-expressed or down-regulated respectively in multiple myeloma patients as disclosed herein.

The present invention also provides a method of developmental stage-based classification for multiple myeloma that is based on gene expression profiling between multiple myeloma cells and normal B or plasma cells.

Other and further aspects, features, and advantages of the present invention will be apparent from the following description of the presently preferred embodiments of the invention. These embodiments are given for the purpose of disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A shows cluster-ordered data table. The clustering is presented graphically as a colored image. Along the vertical axis, the analyzed genes are arranged as ordered by the clustering algorithm. The genes with the most similar patterns of expression are placed adjacent to each other. Likewise, along the horizontal axis, experimental samples are arranged; those with the most similar patterns of expression across all genes are placed adjacent to each other. Both sample and gene groupings can be further described by following the solid lines (branches) that connect the individual components with the larger groups. The color of each cell in the tabular image represents the expression level of each gene, with red representing an expression greater than the mean, green representing an expression less than the mean, and the deeper color intensity representing a greater magnitude of deviation from the mean. FIG. 1B shows amplified gene cluster showing genes downregulated in MM. Most of the characterized and sequence-verified cDNA-encoded genes are known to be immunoglobulins. FIG. 1C shows cluster enriched with genes whose expression level was correlated with tumorigenesis, cell cycle, and proliferation rate. Many of these genes were also statistically significantly upregulated in multiple myeloma (c² and WRS test) (see Table 5). FIG. 1D shows dendrogram of hierarchical cluster. 74 cases of newly diagnosed untreated multiple myeloma, 5 monoclonal gammopathy of undetermined significance, 8 multiple myeloma cell lines, and 31 normal bone marrow plasma cell samples clustered based on the correlation of 5,483 genes (probe sets). Different-colored branches represent normal plasma cell (green), monoclonal gammopathy of undetermined significance (blue arrow), multiple myeloma (tan) and multiple myeloma cell lines (brown arrow). FIG. 1E shows dendrogram of a hierarchical cluster analysis of 74 cases of newly diagnosed untreated multiple myeloma alone (clustergram note shown). Two major branches contained two distinct cluster groups. The subgroups under the right branch, designated MM1 (light blue) and MM2 (blue) were more related to the monoclonal gammopathy of undetermined significance cases in FIG. 1D. The two subgroups under the left branch, designated MM3 (violet) and MM4 (red) represent samples that were more related to the multiple myeloma cell lines in FIG. 1D.

FIGS. 2A-2D show the spike profile distributions of FGFR3 (FIG. 2A), CST6 (FIG. 2B), IFI27 (FIG. 2C), and CCND1 (FIG. 2D) gene expression. The normalized average difference (AD) value of fluorescence intensity of streptavidin-phycoerythrin stained biotinylated cRNA as hybridized to probes sets is on the vertical axis and samples are on the horizontal axis. The samples are ordered from left to right: normal plasma cells (NPCs) (green), MM1 (light blue), MM2 (dark blue), MM3 (violet), and MM4 (red). Note relatively low expression in 31 plasma cells and spiked expression in subsets of multiple myeloma samples. The P values of the test for significant nonrandom spike distributions are P<0.005, P<0.005, P<0.005, and P>0.1, respectively.

FIG. 3A shows a GENECHIP® HUGENEFL® (DNA microarray) analysis of MS4A2 (CD20) gene expression. The normalized average difference (AD) value of fluorescence intensities of streptavidin-phycoerythrin stained biotinylated cRNA as hybridized to two independent probes sets (accession numbers M27394 (blue) and X12530 (red) located in different regions of the MS4A2 gene is on the vertical axis and samples are on the horizontal axis. Note relatively low expression in 31 normal plasma cells (NPCs) and spiked expression in 5 of 74 multiple myeloma samples (multiple myeloma plasma cells). Also note similarity in expression levels detected by the two different probe sets. FIG. 3B shows immunohistochemistry for CD20 expression on clonal multiple myeloma plasma cells: (1) bone marrow biopsy section showing asynchronous type multiple myeloma cells (H&E, ×500); (2) CD20⁺ multiple myeloma cells (100; inset ×500); (3) biopsy from a patient with mixed asynchronous and Marschalko-type multiple myeloma cells (H&E, ×500); and (4) CD20⁺ single lymphocyte and CD20⁻ multiple myeloma cells (×200). CD20 immunohistochemistry was examined without knowledge of clinical history or gene expression findings.

FIGS. 4A-4B show the gene expression correlates with protein expression. Gene and protein expression of CD markers known to be differentially expressed during B-cell differentiation were compared between the multiple myeloma cell line CAG (FIG. 4A) and the Epstein-Barr virus (EBV) transformed B-lymphoblastoid line ARH-77 (FIG. 4B). In both panels, the 8 CD markers are listed in the left column of each panel. Flow cytometric analysis of protein expression is presented in the second column; the average difference (AD) and absolute call (AC) values of gene expression are presented in the third and fourth columns. Note the strong expression of both the gene and protein for CD138 and CD38 in the CAG cells but the low expression in the ARH-77 cells. The opposite correlation is observed for the remaining markers.

FIG. 5 shows multivariate discriminant analysis of 14 features of all normal plasma cells, MMs, monoclonal gammopathy of undetermined significance and multiple myeloma cell lines. This scatterplot resulted from the orthogonal projection of value per case onto the plane defined by the 2 centers. The green plots represent normal plasma cells; the blue plots represent multiple myeloma plasma cells and multiple myeloma cell lines; the pink plots represent monoclonal gammopathy of undetermined significance.

FIG. 6A shows 269 cases of multiple myeloma, 7 multiple myeloma cell lines, 7 monoclonal gammopathy of undetermined significance and 32 normal plasma cells samples clustered based on the correlation of 5,483 genes (probe sets). Two major branches contained two distinct cluster groups. The subgroup including normal plasma cell samples contained 1 monoclonal gammopathy of undetermined significance (green arrow) and 2 misclassified multiple myeloma samples (pink arrow). FIG. 6B shows amplified sample cluster showing samples connecting to the normal group.

FIG. 7 shows multivariate discriminant analysis of 24 features of all multiple myeloma, monoclonal gammopathy of undetermined significance and multiple myeloma cell lines. This scatterplot resulted from the orthogonal projection of value per case onto the plane defined by the 4 centers. The red plots represent the MM1 subgroup; the green plots represent the MM2 subgroup; the blue plots represent the MM3 subgroup; and the pink plots represent the MM4 subgroup; the light blue plots are ungroup cases; and the large yellow plots represent the group centers.

FIG. 8 shows an overview of the strategy used to classify and validate myeloma subgroups described in Example 12.

FIG. 9 shows hierarchic cluster analysis of myeloma samples. Left panel shows thumbnail overview of two-way hierarchic clustering of 177 myeloma specimens (columns) and 2,856 variably expressed genes (rows). Mean-centered gene expression is depicted by a normalized-signal pseudocolor scale. Red and green indicate the genes are overexpressed and underexpressed, respectively. Right panel shows an enlarged view of the sample dendrogram, the color bars stand for the seven different myeloma subtypes. Subpanels I-VII show selected genes whose locations are indicated by vertical colored bars. Because of space limitations, only selected genes are indicated. The dendrogram of the 177 cases at the top of the matrix, in which the pattern and length of branches reflect the relatedness of the samples, indicates that the samples are clustered into seven branches on the basis of similar gene expression profiles.

FIGS. 10A-10D show correlation of spike genes and unique genes with seven subgroups of myeloma. Spike profile distributions of FGFR3, MMSET, MAF, MAFB, CCND1, and CCND3 gene expression among the gene expression-defined myeloma subgroups are shown. Signals from 177 myeloma samples in the training set (FIG. 10A) and from 174 myeloma samples in the testing set (FIG. 10B) are on the vertical axis, and samples are on the horizontal axis. Clearly, patient specimens with CCND1, MAF/MAFB, and FGFR3/MMSET spikes were assigned to group II, group V, and group VII, respectively. FIGS. 10C-10D show supervised hierarchic clustering (specimens shown in columns) of 177 training-set specimens (FIG. 10C) and 174 testing-set specimens (FIG. 10D) versus 350 genes (rows). The genes used in this analysis were the top 50 up-regulated genes chosen by SAM that were most highly correlated with the seven specific class distinctions. The normalized expression value for each gene is indicated by a color, with red representing high expression and green representing low expression. Normalized expression scale is shown at the bottom.

FIGS. 11A-11F show Kaplan-Meier estimates of event-free survival (EFS) and overall survival (OS) in the cluster-defined subgroup samples. Significant differences in event-free survival were present between the subgroups in the training set (FIG. 11A) (p=0.0002), testing set (FIG. 11B) (p=0.021), and predicting set by the 15-gene model (FIG. 11C) (p=0.0014). Significant differences in overall survival were present between the subgroups in the training set (FIG. 11D) (p=0.0033), testing set (FIG. 11E) (p=0.0015), and predicting set (FIG. 11F) by the 15-gene model (p=0.0003).

FIG. 12 shows a 15-gene model representing seven subgroups of myeloma. The data show supervised hierarchic clustering of 177 training-set specimens (left panel) and 174 testing-set specimens (right panel) versus 15 genes (specimens shown in rows, genes shown in columns). The genes used in this analysis were the five genes related to recurrent translocation (FGFR3/MMSET, MAF/MAFB, and CCND1) and the 10 genes chosen by multivariate stepwise discriminant analysis that were most highly correlated with the seven specific class distinctions.

FIG. 13 shows a decision matrix for the 7-group classification using the 15-gene model.

FIG. 14A shows endothelin B receptor (ENDBR) expression in normal plasma cells and in approximately 200 myeloma patients starting with P1 through P226 as indicated by the mean fluorescent intensity of the microarry data depicted on the Y axis. FIG. 14B shows endothelin B receptor expression in normal plasma cells and in newly diagnosed myeloma patients.

FIG. 15A shows the expression of endothelin B receptor (ENDBR) in feeder cells and myeloma cells P323 and P322 before and after co-culture. FIG. 15B shows the expression of endothelin 1 in feeder cells and myeloma cells P323 and P322 before and after co-culture.

FIGS. 16A-16X show flow cytometric, immunofluorescence and cytological analysis of normal B cell and plasma cell samples. CD19-Selected Tonsil B cells: Tonsil-derived mononuclear fractions were tested for percentage of tonsil B cells prior to anti-CD19 immunomagnetic bead sorting by using two-color FACs analysis with antibodies to CD20/CD38 (FIGS. 16A-16B). The post-sorting purity of the tonsil B cell sample was determined by CD20/CD38 (FIGS. 10C-10D), CD138/CD20 (FIG. 10E), and CD138/CD38 (FIG. 16F) staining. Cytospin preparations of the purified tonsil B cell samples were stained with Wright Giemsa and cell morphology observed with light microscopy (FIG. 16G). Purified B cells were also stained with AMCA and FITC antibodies against cytoplasmic immunoglobulin (cIg) light chain k and l and observed by immunofluorescence microscopy (FIG. 16H). Note the lack of cIg staining and thus minimal plasma cell contamination in the tonsil B cell fraction. CD138-Selected Tonsil Plasma Cells: Tonsil mononuclear fractions were tested for percentage of plasma cells prior to anti-CD138 immunomagnetic bead sorting by using two color FACs analysis using antibodies to CD38/CD45 (FIG. 16I) and CD138/CD45 (FIG. 16J). The post-sorting purity of the tonsil plasma cell samples was determined by dual color FACs analysis of CD38/CD45 (FIG. 16K), CD138/CD45 (FIG. 16L), CD38/CD20 (FIG. 16M), and CD138/CD38 (FIG. 16N). Cytospin preparations of the purified tonsil plasma cells were analyzed for morphological appearance (FIG. 16O) and cIg (FIG. 16P). CD138-Selected Bone Marrow Plasma Cells: Mononuclear fractions from bone marrow aspirates were tested for percentage of plasma cells prior to anti-CD138 immunomagnetic bead sorting by using two color FACs analysis using antibodies to CD38/CD45 (FIG. 16Q) and CD138/CD45 (FIG. 16R). The post sorting purity of the bone marrow plasma cell sample was determined by dual color FACs analysis of CD38/CD45 (FIG. 10S), CD138/CD45 (FIG. 16T), CD38/CD20 (FIG. 16U), and CD138/CD38 (FIG. 16V). Cytospin preparations of the purified bone marrow plasma cells were analyzed for morphological appearance (FIG. 16W) and cIg (FIG. 16X). Note the high percentage of cIg-positive bone marrow plasma cells with clear plasma cell morphologic characteristics.

FIG. 17 shows two-dimensional hierarchical cluster analysis of normal human plasma cells. Included were 7 tonsil BC (TBC), 7 tonsil PC (TPC), and 7 bone marrow PC (BPC) samples clustered based on the correlation of experimental expression profiles of 4866 probe sets. The clustering is presented graphically as a colored image. Along the vertical axis, the analyzed genes are arranged as ordered by the clustering algorithm. The genes with the most similar patterns of expression are placed adjacent to each other. Experimental samples are similarly arranged in the horizontal axis. The color of each cell in the tabular image represents the expression level of each gene, with red representing an expression greater than the mean, green representing an expression less than the mean, and the deeper color intensity representing a greater magnitude of deviation from the mean. The top dendrogram produces two major branches separating tonsil BCs from PCs. In addition, within the PC cluster, tonsil PCs and bone marrow PCs are separated on three unique branches.

FIG. 18 shows two-dimensional hierarchical cluster analysis of experimental expression profiles and gene behavior of 30 EDG-MM. B cells, tonsil and bone marrow plasma cells, and multiple myeloma (MM) samples were analyzed using a cluster-ordered data table. The tonsil B cell, tonsil plasma cell, bone marrow plasma cell samples are indicated by red, blue, and golden bars respectively. The nomenclature for the 74 MM samples is as indicated in Zhan et al. (1). Along the vertical axis, the analyzed genes are arranged as ordered by the clustering algorithm. The genes with the most similar patterns of expression are placed adjacent to each other. Both sample and gene groupings can be further described by following the solid lines (branches) that connect the individual components with the larger groups. The tonsil B cell cluster is identified by the horizontal red bar. The color of each cell in the tabular image represents the expression level of each gene, with red representing an expression greater than the mean, green representing an expression less than the mean, and the deeper color intensity representing a greater magnitude of deviation from the mean.

FIG. 19 shows two-dimensional hierarchical cluster analysis of experimental expression profiles and gene behavior of 50 LDG-MM1 genes. Genes are plotted along the vertical axis (right side), and experimental samples are plotted along the top horizontal axis by their similarity. The tonsil plasma cell cluster is identified by a horizontal blue bar. Tonsil B cell, tonsil plasma cell, and bone marrow plasma cell samples are indicated as in FIG. 18.

FIG. 20 shows two-dimensional hierarchical cluster analysis of experimental expression profiles and gene behavior of 50 LDG-MM2 genes. Genes are plotted along the vertical axis (right side), and experimental samples are plotted along the top horizontal axis by their similarity. The bone marrow plasma cell cluster is identified by a horizontal golden bar. Tonsil B cell, tonsil plasma cell, and bone marrow plasma cell samples are indicated as in FIG. 18.

FIG. 21 shows variation in expression of proliferation genes reveals similarities between tonsil B cells and MM4. The data are shown as boxplot of Kruskal-Wallis test values. The seven groups analyzed (tonsil B cells, tonsil plasma cells, bone marrow plasma cells, and gene expression defined subgroups MM1, MM2, MM3, and MM4) are distributed along the x-axis and the natural log transformed average difference is plotted on the y axis. EZH2; p=7.61×10⁻¹¹; KNSL1, p=3.21×10⁻⁸; PRKDC, p=2.86×10⁻¹¹; SNRPC, p=5.44×10⁻¹²; CCNB1, p=2.54×10⁻⁸; CKS2, p=9.49×10⁻¹¹; CKS1, p=5.86×10⁻⁹; PRIM1, p=4.25×10⁻⁵. XBP1 is significantly up-regulated between tonsil B cells and tonsil plasma cells as expected

FIG. 22 shows the receiver operating characteristic (ROC) curves for the multiple myeloma (MM) vs monoclonal gammopathy of undetermined significance (MGUS) classification.

FIG. 23A shows global gene expression patterns reflect bone lesions in multiple myeloma. Clusterview of normalized expression levels of 58 genes identified by logistic regression and permutation analysis as being significantly differentially expressed in malignant plasma cells from patients with 0 (n=36) and 1+ MRI focal lesions (n=137) (p<0.0001). The 28 genes exhibiting overexpression in plasma cells from patients with 1+ MRI lesions are ordered from top to bottom based on the significance rank. Likewise the 30 genes showing significant elevation in patients with no MRI-lesions are ordered from bottom to top based on significance rank. Expression scales range from −3 (blue) to +3 (red) as indicated below the data display. DKK1 ranked 4th in significance. FIG. 23B shows Log 2 DKK1 expression was correlated with bone lesions. Box plots of DKK1 gene expression levels in purified plasma cells in relation to lesions detected by MRI, x-ray, and MRI and xray. Odds ratios for relative risk and associated p values are presented in the text.

FIGS. 24A-24H shows DKK1 protein expression is restricted to plasma cells in the bone marrow. Expression of DKK1 and cytoplasmic immunoglobulin (cIg) kappa or lambda light chain was examined by immunohistochemistry (FIGS. 24A-24D) and immunofluorescence (FIGS. 24E-24H) staining of bone marrow biopsies and bone marrow aspirates, respectively. DKK1 protein expression in representative examples from a patient with low (FIGS. 24A, 24C) and high (FIGS. 24B, 24D) DKK1 gene expression are correlated. FIGS. 24A-24B and 24E-24F are stained for cIg; FIGS. 24C-24D and 24G-24H are stained for DKK1. Note that both biopsies (FIGS. 24A-24B) stain brightly for cIg, but only the case with high DKK1 gene expression (FIG. 24B) shows DKK1 protein expression (FIG. 24D). All images are at 250× magnification. Immunofluorescence staining was performed on mononuclear cells from bone marrow aspirates of a multiple myeloma patient (FIGS. 24E, 24G) and a normal healthy donor (FIGS. 24F, 24H). Note that only plasma cells stain for DKK1 in both multiple myeloma and normal bone marrow (arrows, FIGS. 24E, 24G, indicate neutrophil nuclear morphology). Also note that not all plasma cells in normal marrow (FIGS. 24F, 24H) are DKK1 positive (see arrows). All images are at 1000× magnification.

FIGS. 25A-25B show DKK1 protein in the serum is highly correlated with DKK1 gene expression and the presence of bone lesions. FIG. 25A shows the expression of DKK1 mRNA and proteins detected by microarray and ELISA respectively and both of the results were transformed by the log base 2 and normalized to give a mean of 0 and variance of 1. Each bar indicates the relative relationship between each sample. There was a strong significant correlation between DKK1 transcripts and protein (r=0.65, p<0.0001). FIG. 25B shows box plots of bone marrow serum DKK1 protein levels in relation to lesions detected by MRI, x-ray, and MRI and x-ray. Odds ratios for relative risk and associated p values are presented in the text.

FIG. 26 shows multiple myeloma serum can block alkaline phosphatase production in BMP-2 treated C2C12 cells in a DKK1-dependent manner. Twenty thousand C2C12 cells were cultured for 5 days in the presence of 100 ng/ml BMP2, BMP2+10% normal bone marrow serum (NS), BMP2+10% multiple myeloma bone marrow serum from 2 patients (MMS1 and MMS2), or BMP2+10% multiple myeloma patient serum after pre-incubation with goat anti-DKK1 or goat polyclonal IgG 30 minutes at RT. Alkaline phosphatase levels were determined and each bar represents the mean (±SEM) of triplicate determinants. Data were analyzed by Wilcoxon test after establishing homogeneity of variances. * Indicates p<0.05 in comparison to ALP in BMP2+10% normal serum.

DETAILED DESCRIPTION OF THE INVENTION

There is now strong evidence that global gene expression profiling can reveal molecular heterogeneity of similar or related hematopoietic malignancies that have been difficult to distinguish. Genes exhibiting significant differential expression between normal and malignant cells can be used in the development of clinically relevant diagnostics as well as provide clues into the basic mechanisms of cellular transformation. In fact, these profiles might even be used to identify malignant cells even in the absence of any clinical manifestations. In addition, biochemical pathways in which the products of these genes act may be targeted by novel therapeutics.

The present invention demonstrates both normal and malignant plasma cells can be purified to homogeneity from bone marrow aspirates using anti-CD138-based immunomagnetic bead-positive selection. Using these cells, the present invention provides the first comprehensive global gene expression profiling of newly diagnosed multiple myeloma patients and contrasted these expression patterns with those of normal plasma cells. Novel candidate multiple myeloma disease genes were identified and this profiling leads to development of a gene-based classification system for multiple myeloma.

Results from hierarchical cluster analysis on multiple myeloma plasma cells and normal plasma cells, as well as the benign plasma cell dyscrasia monoclonal gammopathy of undetermined significance and end-stage-like multiple myeloma cell lines revealed normal plasma cells are unique and that primary multiple myeloma is either like monoclonal gammopathy of undetermined significance or multiple myeloma cell lines. In addition, multiple myeloma cell line gene expression was homogeneous as evidenced by tight clustering in the hierarchical analysis. Similarity of multiple myeloma cell line expression patterns to primary newly diagnosed forms of multiple myeloma support the validity of using multiple myeloma cell lines as models for multiple myeloma.

Four distinct clinical multiple myeloma subgroups (MM1 to MM4) were distinguished upon hierarchical clustering of multiple myeloma. The MM1 subgroup contained samples that were more like monoclonal gammopathy of undetermined significance, whereas the MM4 subgroup contained samples more like multiple myeloma cell lines. The most significant gene expression patterns differentiating MM1 and MM4 were cell cycle control and DNA metabolism genes, and the MM4 subgroup was more likely to have abnormal cytogenetics, elevated serum b2M, elevated creatinine, and deletions of chromosome 13. These are important variables that historically have been linked to poor prognosis.

Gene Expression Changes in Multiple Myeloma

Data disclosed herein indicated that the MM4 subgroup likely represents the most high-risk clinical entity. Thus, knowledge of the molecular genetics of this particular subgroup should provide insight into its biology and possibly provide a rationale for appropriate subtype-specific therapeutic interventions. The most significant gene expression changes differentiating the MM1 and MM4 subgroups code for activities that clearly implicate MM4 as having a more proliferative and autonomous phenotype. The most significantly altered gene in the comparison, TYMS (thymidylate synthase), which functions in the prymidine biosynthetic pathway, has been linked to resistance to fluoropyrimidine chemotherapy and also poor prognosis in colorectal carcinomas. Other notable genes upregulated in MM4 were the CAAX farnesyltransferase gene, FTNA. Farnesyltransferase prenylates RAS, a post translational modification required to allow RAS to attach to the plasma membrane. These data suggest that farnesyltransferase inhibitors may be effective in treating patients with high levels of FTNA expression.

Two other genes coding for components of the proteasome pathway, POH1 (26S proteasome-associated pad1 homolog) and UBL1 (ubiquitin-like protein 1) were also overexpressed in MM4. Overexpression of POH1 confers P-glycoprotein-independent, pleotropic drug resistance to mammalian cells. UBL1, also known as sentrin, is involved in many processes including associating with RAD51, RAD52, and p53 proteins in the double-strand repair pathway; conjugating with RANGAP1 involved in nuclear protein import; and importantly for multiple myeloma, protecting against both Fas/Apo-1 (TNFRSF6) or TNFR1-induced apoptosis. In contrast to normal plasma cells, more than 75% of multiple myeloma plasma cells express abundant mRNA for the multidrug resistance gene, lung-resistance-related protein (MVP). These data are consistent with previous reports showing expression of MVP in multiple myeloma is a poor prognostic factor. Given the uniform development of chemotherapy resistance in multiple myeloma, the combined overexpression of POH1 and MVP may have profound influences on this phenotype. The deregulated expression of many genes whose products function in the proteasome pathway may be used in pharmacogenomic analysis in determining the efficacy of proteasome inhibitors like PS-341 (Millennium Pharmaceuticals, Cambridge, Mass.).

Another significantly upregulated gene in MM4 was the single stranded DNA-dependent ATP-dependent helicase (G22P1), which is also known as Ku70 autoantigen. The DNA helicase II complex, made up of p70 and p80, binds preferentially to fork-like ends of double-stranded DNA in a cell cycle-dependent manner. Binding to DNA is thought to be mediated by p70 and dimerization with p80 forms the ATP-dependent DNA-unwinding enzyme (helicase II) and acts as the regulatory component of a DNA-dependent protein kinase (DNPK) which was also significantly upregulated in MM4. The involvement of helicase II complex in DNA double-strand break repair, V(D)J recombination, and notably chromosomal translocations has been proposed. Another upregulated gene was the DNA fragmentation factor (DFFA). Caspase-3 cleaves DFFA-encoded 45 kD subunit at two sites to generate an active factor that produces DNA fragmentation during apoptosis signaling. In light of the many blocks to apoptosis in multiple myeloma, DFFA activation could result in DNA fragmentation, which in turn would activate the helicase II complex that may facilitate chromosomal translocations. It is of note that abnormal karyotypes, and thus chromosomal translocations, are associated with the MM4 subgroup which tended to overexpress these two genes.

Hence, results disclosed herein demonstrate that direct comparison of gene expression patterns in multiple myeloma and normal plasma cells can identified novel genes that could represent fundamental changes associated with malignant transformation of plasma cells.

Progression of multiple myeloma as a hypoproliferative tumor is thought to be linked to a defect in programmed cell death rather than rapid cell replication. Two genes, prohibitin (PHB) and quiescin Q6 (QSCN6), overexpressed in multiple myeloma are involved in growth arrest. Overexpression of these genes may be responsible for the typically low proliferation indices seen in multiple myeloma. It is hence conceivable that therapeutic downregulation of these genes that results in enhanced proliferation could render multiple myeloma cells more susceptible to cell cycle-active chemotherapeutic agents.

The gene coding for CD27, TNFRSF7, the second most significantly underexpressed gene in multiple myeloma, is a member of the tumor necrosis factor receptor (TNFR) superfamily that provides co-stimulatory signals for T and B cell proliferation, B cell immunoglobulin production and apoptosis. Anti-CD27 significantly inhibits induction of Blimp-1 and J-chain transcripts which are turned on in cells committed to plasma cell differentiation, suggesting that ligation of CD27 on B cells may prevent terminal differentiation. CD27 ligand (CD70) prevents IL-10-mediated apoptosis and directs differentiation of CD27⁺ memory B cells toward plasma cells in cooperation with IL-10. Thus, it is possible that downregulation of CD27 gene expression in multiple myeloma may block an apoptotic program.

Overexpression of CD47 in multiple myeloma may be related to escape of multiple myeloma cells from immune surveillance. Studies have shown that cells lacking CD47 are rapidly cleared from the bloodstream by splenic red pulp macrophages and CD47 on normal red blood cells prevents this elimination.

The gene product of DNA methyltransferase 1, DNMT1, overexpressed in multiple myeloma is responsible for cytosine methylation in mammals and has an important role in epigenetic gene silencing. In fact, aberrant hypermethylation of tumor suppressor genes plays an important role in the development of many tumors. De novo methylation of p16/INK4α is a frequent finding in primary multiple myeloma. Also, recent studies have shown that upregulated expression of DNMTs may contribute to the pathogenesis of leukemia by inducing aberrant regional hypermethylation. DNA methylation represses genes partly by recruitment of the methyl-CpG-binding protein MeCP2, which in turn recruits a histone deacetylase activity. It has been shown that the process of DNA methylation mediated by Dnmt1 may depend on or generate an altered chromatin state via histone deacetylase activity. It is potentially significant that multiple myeloma cases also demonstrate significant overexpression of metastasis-associated 1 (MTA1) gene. MTA1 was originally identified as being highly expressed in metastatic cells. MTA1 has more recently been discovered to be one subunit of the NURD (NUcleosome Remodeling and histone Deacetylation) complex which contains not only ATP-dependent nucleosome disruption activity, but also histone deacetylase activity. Thus, over expression of DNMT1 and MTA1 may have dramatic effects on repressing gene expression in multiple myeloma.

Oncogenes activated in multiple myeloma included ABL and MYC. Although it is not clear whether ABL tyrosine kinase activity is present in multiple myeloma, it is important to note that overexpression of abl and c-myc results in accelerated development of mouse plasmacytomas. Thus, it may be more than a coincidence that multiple myeloma cells significantly overexpresses MYC and ABL.

Chromosomal translocations involving the MYC oncogene and IGH and IGL genes that result in dysregulated MYC expression are hallmarks of Burkitt's lymphoma and experimentally induced mouse plasmacytomas; however, MYC/IGH-associated translocations are rare in multiple myeloma. Although high MYC expression was a common feature in our panel of multiple myeloma, it was quite variable, ranging from little or no expression to highly elevated expression. It is also of note that the MAZ gene whose product is known to bind to and activate MYC expression was significantly upregulated in the MM4 subgroup. Given the important role of MYC in B cell neoplasia, it is speculated that overexpression of MYC, and possibly ABL, in multiple myeloma may have biological and possibly prognostic significance.

EXT1 and EXT2, which are tumor suppressor genes involved in hereditary multiple exostoses, heterodimerize and are critical in the synthesis and display of cell surface heparan sulfate glycosaminoglycans (GAGs). EXT1 is expressed in both multiple myeloma and normal plasma cells. EXT2L was overexpressed in multiple myeloma, suggesting that a functional glycosyltransferase could be created in multiple myeloma. It is of note that syndecan-1 (CD138/SDC1), a transmembrane heparan sulfate proteoglycan, is abundantly expressed on multiple myeloma cells and, when shed into the serum, is a negative prognostic factor. Thus, abnormal GAG-modified SDC1 may be important in multiple myeloma biology. The link of SDC1 to multiple myeloma biology is further confirmed by the recent association of SDC1 in the signaling cascade induced by WNT proto-oncogene products. It has been showed that syndecan-1 (SDC1) is required for Wnt-1-induced mammary tumorigenesis. Data disclosed herein indicated a significant downregulation of WNT10B in primary multiple myeloma cases. It is also of note that the WNT5A gene and the FRZB gene, which codes for a decoy WNT receptor, were also marginally upregulated in newly diagnosed multiple myeloma. Given that WNTs represent a novel class of B cell regulators, deregulating the expression of these growth factors (WNT5A, WNT10B) and their receptors (e.g., FRZB) and genes products that modulate receptor signaling (e.g., SDC1) may be important in the genesis of multiple myeloma.

Genes identified by the present invention that shows significantly up-regulated or down-regulated expression in multiple myeloma are potential therapeutic targets for multiple myeloma. Over-expressed genes may be targets for small molecules or inhibitors that decrease their expression. Methods and materials that can be used to inhibit gene expression, e.g. small drug molecules, anti-sense oligo, or antibody would be readily apparent to a person having ordinary skill in this art. On the other hand, under-expressed genes can be replaced by gene therapy or induced by drugs.

Gene Profiles Defining Disease Subgroups

The present invention also identifies, through multivariate stepwise discriminant analysis, a minimum subset of genes whose expression is intimately associated with malignant features of multiple myeloma. By applying linear regression analysis to the top 50 differentially expressed genes, 14 genes were defined as predictors that are able to differentiate multiple myeloma from normal plasma cells with a high degree of accuracy. When the model was applied to a validation group consisting of 118 multiple myeloma, 6 normal plasma cells and 7 cases of monoclonal gammopathy of undetermined significance (MGUS), an accuracy of classification of more than 99% was achieved. Importantly, 6 of the 7 MGUS cases were classified as multiple myeloma, indicating that MGUS has gene expression features of malignancy. Thus the altered expression of 14 genes out of over 6,000 genes interrogated are capable of defining multiple myeloma. Similar multivariate discriminant analysis also identified a set of 24 genes that can distinguish between the four multiple myeloma subgroups described above.

In addition to identifying genes that were statistically different between normal plasma cells and multiple myeloma plasma cells, the present invention also identified genes, like FGFR3 and CCND1, that demonstrate highly elevated “spiked” expression in subsets of multiple myelomas. Patients with elevated expression of these genes can have significant distribution differences among the four gene expression cluster subgroups. For example, FGFR3 spikes are found in MM1 and MM2 whereas spikes of IFI27 are more likely to be found in MM3 and MM4. Highly elevated expression of the interferon-induced gene IFI27 may be indicative of viral infection, either systemic or specifically within the plasma cells from these patients. Correlation analysis has shown that IFI27 spikes are significantly linked (Pearson correlation coefficient values of 0.77 to 0.60) to elevated expression of 14 interferon-induced genes, including MX1, MX2, OAS1, OAS2, IFIT1, IFIT4, PLSCR1, and STAT1. More recent analysis of a large population of multiple myeloma patients (N=280) indicated that nearly 25% of all patients had spikes of the IFI27 gene. It is of interest to determine whether or not the IFI27 spike patients who cluster in the MM4 subgroup are more likely to have a poor clinical course and to identify the suspected viral infection causing upregulation of this class of genes. In conclusion, spiked gene expression may also be used in the development of clinically relevant prognostic groups.

Finally, the 100% coincidence of spiked FGFR3 or CCND1 gene expression with the presence of t(4;14)(p14;q32) or t(11;14)(q13;q32) translocations, as well as the strong correlations between protein expression and gene expression represent important validations of the accuracy of gene expression profiling and suggests gene expression profiling may eventually supplant the labor intensive and expensive clinical laboratory procedures, such as cell surface marker immunophenotyping and molecular and cellular cytogenetics.

In another embodiment, the present example also uses feature-subset selection to extract genes relevant to specific myeloma subtypes. In this regard, multivariate stepwise discriminant analysis was applied and identified 15 genes that could correctly separate tissue samples into seven subtypes. Examining the expression of the 15 genes identified herein not only would provide important new insights into the diagnosis and pathogenesis of these myeloma subtypes but also may pinpoint useful targets against which novel therapeutic agents could be developed.

Comparison of Multiple Myeloma with Normal Plasma Cell Development

Data disclosed herein indicate that multiple myeloma can be placed into a developmental schema parallel to that of normal plasma cell differentiation. Global gene expression profiling reveals distinct changes in transcription associated with human plasma cell differentiation. Hierarchical clustering analyses with 4866 genes segregated tonsil B cells, tonsil plasma cells, and bone marrow plasma cells. Combining c² and Wilcoxon rank sum tests, 359 previously defined and novel genes significantly (p<0.0005) discriminated tonsil B cells from tonsil plasma cells, and 500 genes significantly discriminated tonsil plasma cells from bone marrow plasma cells. Genes that were differentially expressed in the tonsil B cell to tonsil plasma cell transition were referred as “early differentiation genes” (EDGs) and those differentially expressed in the tonsil plasma cell to bone marrow plasma cell transition were referred as “late differentiation genes” (LDGs). One-way ANOVA was then applied to EDGs and LDGs to identify statistically significant expression differences between multiple myeloma (MM) and tonsil B cells (EDG-MM), tonsil plasma cells (LDG-MM1), or bone marrow plasma cells (LDG-MM2).

Hierarchical cluster analysis revealed that 13/18 (p=0.00005) MM4 cases (a putative poor-prognosis subtype) clustered tightly with tonsil B cells. The other groups (MM1, 2 and 3) failed to show such associations. In contrast, there was tight clustering between tonsil plasma cells and 14/15 (p=0.00001) MM3, and significant similarities were found between bone marrow plasma cells and 14/20 (p=0.00009) MM2 cases. MM1 showed no significant linkage with the normal cell types studied. In addition, XBP1, a transcription factor essential for plasma cell differentiation, exhibited a significant, progressive reduction in expression from MM1 to MM4, consistent with developmental-stage relationships. Therefore, global gene expression patterns linked to late-stage B cell differentiation confirmed and extended a global gene expression-defined classification system of multiple myeloma, suggesting that multiple myeloma represents a constellation of distinct subtypes of disease with unique origins.

In summary, the present invention is drawn to a method of gene expression profiling for multiple myeloma. Nucleic acid samples of isolated plasma cells derived from individuals with or without multiple myeloma were applied to a DNA microarray, and hierarchical clustering analysis performed on data obtained from the microarray will classify the individuals into distinct subgroups such as the MM1, MM2, MM3 and MM4 subgroups disclosed herein. Gene expression profiling will also identify genes with elevated expression in subsets of multiple myeloma patients or genes with significantly different levels of expression in multiple myeloma patients as compared to normal individuals. These genes are potential therapeutic targets for multiple myeloma. Representative examples of these genes are listed in Tables 4, 5 and 8.

In another embodiment, there is provided a method of identifying a group of genes that can distinguish between normal plasma cells and plasma cells of multiple myeloma. Nucleic acid samples of isolated plasma cells derived from individuals with or without multiple myeloma were applied to a DNA microarray, and hierarchical clustering analysis was performed on data obtained from the microarray. Genes with statistically significant differential expression patterns were identified, and linear regression analysis was used to identify a group of genes that is capable of accurate discrimination between normal plasma cells and plasma cells of multiple myeloma. Representative examples of these genes are listed in Table 6. This analysis can also identify a group of genes that is capable of accurate discrimination between subgroups of multiple myeloma. Representative examples of these genes are listed in Table 7.

Expression levels of a group of 14 genes as listed in Table 6 or a group of 24 genes as listed in Table 7 could be used for diagnosis of multiple myeloma. Significant differential expression of these genes would indicate that such individual has multiple myeloma or a subgroup of multiple myeloma. Gene expression levels can be examined at nucleic acid level or protein level according to methods well known to one of skill in the art.

In another embodiment, there is provided a method of diagnosis for multiple myeloma based on examining the expression levels of a group of genes comprising CST6, RAB7L1, MAP4K3, HRASLS2, TRAIL, IG, FGL2, GNG11, MCM2, FLJ10709, CCND1, MAF, MAFB, FGFR3, and MMSET. CCND1, MAF, MAFB, FGFR3, and MMSET expression can be determined by and are correlated with chromosomal translocation such as t(4;14)(p21;q32), t(14;16)(q32;q23), t(14;20)(q32;q13), and t(11;14)(q13;q32). Gene expression levels of this group of genes would classify an individual into one of 7 groups of myeloma (groups 1-7). Individual in myeloma groups 1, 2, 3 and 6 would have poor prognosis compared to individual in myeloma groups 4, 5 and 7. Group 1 is defined by downregulation of CST6, RAB7L1, MAP4K3, HRASLS2, GNG11, MCM2 and FLJ10709, and overexpression of TRAIL, IG and FGFL2. Group 2 is defined by downregulation of CST6, RAB7L1, MAP4K3, HRASLS2, IG, FGFL2, MCM2 and FLJ10709, and overexpression of TRAIL and GNG11. Group 3 is defined by overexpression of CCND1, or translocation t(11;14)(q13;q32). Group 4 is defined by downregulation of CST6, RAB7L1, MAP4K3, HRASLS2, IG, FGFL2, and GNG11, and overexpression of TRAIL, MCM2 and FGFL2. Group 5 is defined by overexpression of MAF or MAFB, or translocation t(14;16)(32;q23) or t(14;20)(q32;q13). Group 6 is defined by overexpression of CST6, RAB7L1, MAP4K3, and HRASLS2, and downregulation of TRAIL. Group 7 is defined by overexpression of FGFR3 or MMSET, or translocation t(4;14)(p21;q32).

In yet another embodiment of the present invention, there are provided methods of treatment for multiple myeloma. Such methods involve inhibiting expression of one of the genes listed in Table 5 or Table 8, or increasing expression of one of the genes listed in Table 4. Methods of inhibiting or increasing gene expression such as those using anti-sense oligonucleotide or antibody are well known to one of skill in the art. Inhibiting gene expression can be achieved through RNA interference using so called siRNA. Gene expression enhancement might be through gene therapy.

The present invention is also drawn to a method of developmental stage-based classification for multiple myeloma. Nucleic acid samples of isolated B cells and plasma cells derived from individuals with or without multiple myeloma were applied to a DNA microarray, and hierarchical clustering analysis performed on data obtained from the microarray will classify the multiple myeloma cells according to the developmental stages of normal B cells and plasma cells. In general, normal B cells and plasma cells are isolated from tonsil, bone marrow, mucosal tissue, lymph node or peripheral blood.

The present invention also provides a method of controlling bone loss in an individual by inhibiting the expression of the DKK1 gene (accession number NM012242). In general, DKK1 expression can be inhibited by anti-sense oligonucleotides or anti-DKK1 antibodies. In another embodiment, bone loss can be controlled by a pharmacological inhibitor of DKK1 protein. Preferably, the individual having bone loss may have multiple myeloma, osteoporosis, post-menopausal osteoporosis or malignancy-related bone loss that is caused by breast cancer metastasis or prostate cancer metastasis.

The following examples are given for the purpose of illustrating various embodiments of the invention and are not meant to limit the present invention in any fashion. One skilled in the art will appreciate readily that the present invention is well adapted to carry out the objects and obtain the ends and advantages mentioned, as well as those objects, ends and advantages inherent herein. Changes therein and other uses which are encompassed within the spirit of the invention as defined by the scope of the claims will occur to those skilled in the art.

EXAMPLE 1 Cell Isolation and Analysis

Samples for the following studies included plasma cells from 74 newly diagnosed cases of multiple myeloma, 5 subjects with monoclonal gammopathy of undetermined significance, 7 samples of tonsil B lymphocytes (tonsil BCs), 11 samples of tonsil plasma cells (tonsil PCs), and 31 bone marrow PCs derived from normal healthy donor. Multiple myeloma cell lines (U266, ARP1, RPMI-8226, UUN, ANBL-6, CAG, and H929 (courtesy of P. L. Bergsagel) and an Epstein-Barr virus (EBV)-transformed B-lymphoblastoid cell line (ARH-77) were grown as recommended (ATCC, Chantilly, Va.).

Tonsils were obtained from patients undergoing tonsillectomy for chronic tonsillitis. Tonsil tissues were minced, softly teased and filtered. The mononuclear cell fraction from tonsil preparations and bone marrow aspirates were separated by a standard Ficoll-Hypaque gradient (Pharmacia Biotech, Piscataway, N.J.). The cells in the light density fraction (S.G.≦1.077) were resuspended in cell culture media and 10% fetal bovine serum, RBC lysed, and several PBS wash steps were performed. Plasma cell isolation was performed with anti-CD138 immunomagnetic bead selection as previously described (1). B lymphocyte isolation was performed using directly conjugated monoclonal mouse anti-human CD19 antibodies and the AUTOMACS automated cell sorter (Miltenyi-Biotec, Auburn, Calif.).

For cytology, approximately 40,000 purified tonsil BC and PC mononuclear cells were cytocentrifuged at 1000×g for 5 min at room temperature. For morphological studies, the cells were immediately processed by fixing and staining with DIFFQUICK fixative and stain (Dade Diagnostics, Aguada, PR).

For immunofluorescence, slides were treated essentially as described (2). Briefly, slides were air-dried overnight, then fixed in 100% ethanol for 5 min at room temperature and baked in a dry 37° C. incubator for 6 hr. The slides were then stained with 100 μl of a 1:20 dilution of goat anti-human-kappa immunoglobulin light chain conjugated with 7-amino-4-methylcourmarin-3-acitic acid (AMCA) (Vector Laboratories, Burlingame, Calif.) for 30 min in a humidified chamber. After incubation, the slides were washed two times in 1× PBS+0.1% NP-40 (PBD). To enhance the AMCA signal, the slides were incubated with 100 μl of a 1:40 dilution of AMCA-labeled rabbit-anti-goat IgG antibody and incubated for 30 min at room temperature in a humidified chamber. Slides were washed 2 times in 1× PBD. The slides were then stained with 100 μl of a 1:100 dilution of goat anti-human-lambda immunoglobulin light chain conjugated with FITC (Vector Laboratories, Burlingame, Calif.) for 30 min in a humidified chamber; the slides were washed two times in 1× PBD. Then the slides were stained with propidium iodide at 0.1 mg/ml in 1× PBS for 5 min, washed in 1× PBD, and 10 μl anti-fade (Molecular Probes, Eugene, Oreg.) was added and coverslips were placed. Cytoplasmic immunoglobulin light chain-positive PCs were visualized using an OLYMPUS BX60 epi-fluorescence microscope equipped with appropriate filters. The images were captured using a Quips XL genetic workstation (Vysis, Downers Grove, Ill.).

Both unpurified mononuclear cells and purified fractions from tonsil BCs, tonsil PCs, and bone marrow PCs were subjected to flow cytometric analysis of CD marker expression using a panel of antibodies directly conjugated to FITC or PE. Markers used in the analysis included FITC-labeled CD20, PE-labeled CD38, FITC-labeled or ECD-labeled CD45, PE- or PC5-labled CD138 (Beckman Coulter, Miami, Fla.). For detection of CD138 on PCs after CD138 selection, we employed an indirect detection strategy using a FITC-labeled rabbit anti-mouse IgG antibody (Beckman Coulter) to detect the mouse monoclonal anti-CD138 antibody BB4 used in the immunomagnetic selection technique. Cells were taken after Ficoll Hypaque gradient or after cell purification, washed in PBS, and stained at 4° C. with CD antibodies or isotype-matched control G1 antibodies (Beckman Coulter). After staining, cells were resuspended in 1× PBS and analyzed using a EPICS XL-MCL flow cytometry system (Beckman Coulter).

EXAMPLE 2

Preparation of Labeled cRNA and Hybridization to High-Density Microarray

Total RNA was isolated with RNEASY Mini Kit (Qiagen, Valencia, Calif.). Double-stranded cDNA and biotinylated cRNA were synthesized from total RNA and hybridized to HuGeneFL GENECHIP microarrays (Affymetrix, Santa Clara, Calif.), which were washed and scanned according to procedures developed by the manufacturer. The arrays were scanned using Hewlett Packard confocal laser scanner and visualized using AFFYMETRIX 3.3 software (Affymetrix). Arrays were scaled to an average intensity of 1,500 and analyzed independently.

EXAMPLE 3 Genechip Data Analysis

To efficiently manage and mine high-density oligonucleotide DNA microarray data, a new data-handling tool was developed. GeneChip-derived expression data was stored on an MS SQL Server. This database was linked, via an MS Access interface called Clinical Gene-Organizer to multiple clinical parameter databases for multiple myeloma patients. This Data Mart concept allows gene expression profiles to be directly correlated with clinical parameters and clinical outcomes using standard statistical software. All data used in the present analysis were derived from Affymetrix 3.3 software. GeneChip 3.3 output files are given (1) as an average difference (AD) that represents the difference between the intensities of the sequence-specific perfect match probe set and the mismatch probe set, or (2) as an absolute call (AC) of present or absent as determined by the GeneChip 3.3 algorithm. Average difference calls were transformed by the natural log after substituting any sample with an average difference of <60 with the value 60 (2.5 times the average Raw Q). Statistical analysis of the data was performed with software packages SPSS 10.0 (SPSS, Chicago, Ill.), S-Plus 2000 (Insightful Corp., Seattle, Wash.), and Gene Cluster/Treeview (Eisen et al., 1998).

To differentiate four distinct subgroups of multiple myeloma (MM1, MM2, MM3 and MM4), hierarchical clustering of average linkage clustering with the centered correlation metric was employed. The clustering was done on the average difference data of 5,483 genes. Either Chi square (c²) or Fisher's exact test was used to find significant differences between cluster groups with the AC data. To compare the expression levels, the non-parametric Wilcoxon rank sum (WRS) test was used. This test uses a null hypothesis that is based on ranks rather than on normally distributed data. Before the above tests were performed, genes that were absent (AC) across all samples were removed; 5,483 genes were used in the analyses. Genes that were significant (p<0.0001) for both the c² test and the WRS test were considered to be significantly differentially expressed.

Clinical parameters were tested across multiple myeloma cluster groups. ANOVA test was used to test the continuous variables, and c² test of independence or Fisher's exact test was applied to test discrete variables. The natural log of the average difference data was used to find genes with a “spiked profile” of expression in multiple myeloma. Genes were identified that had low to undetectable expression in the majority of patients and normal samples (no more than 4 present absolute calls [P-AC]). A total of 2,030 genes fit the criteria of this analysis. The median expression value of each of the genes across all patient samples was determined. For the i^(th) gene, this value was called medgene (i). The i^(th) gene was a “spiked” gene if it had at least 4 patient expression values>2.5+medgene (i). The constant 2.5 was based on the log of the average difference data. These genes that were “spiked” were further divided into subsets according to whether or not the largest spike had an average difference expression value greater than 10,000.

To determine transcriptional changes associated with human plasma cell differentiation, a total of 4866 genes were scanned across 7 cases each of tonsil B cells, tonsil plasma cells, and bone marrow plasma cells. The 4866 genes were derived from 6800 by filtering out all control genes, and genes not fulfilling the test of Max-Min<1.5 (1.5 being the natural log of the average difference). The c² test was used to eliminate genes with absent absolute call (AAC). For example, in the tonsil plasma cell to bone marrow plasma cell comparison, genes with c² values greater than 3.84 (p<0.05) or having “present” AC (PAC) in more than half of the samples in each group were retained. In the tonsil B cell to tonsil plasma cell and tonsil plasma cell to bone marrow plasma cell comparisons, 2662 and 2549 genes were retained as discriminating between the two groups, respectively. To compare gene expression levels, the non-parametric Wilcoxon Rank Sum (WRS) test was used to compare two groups using natural log transformed AD. The cutoff p value depended on the sample size, the heterogeneity of the two comparative populations (tonsil B cells, tonsil plasma cells, and bone marrow plasma cells showed a higher degree of stability in AD), and the degree of significance. In this analysis, 496 and 646 genes were found to be significantly (p<0.0005) differentially expressed in the tonsil B cell versus tonsil plasma cell and tonsil plasma cell versus bone marrow plasma cell comparisons, respectively. To define the direction of significance (expression changes being up or down in one group compared with the other), the non-parametric Spearman correlation test of the AD was employed.

Genes that were significantly differentially expressed in the tonsil B cell to tonsil plasma cell transition were referred as “early differentiation genes” (EDGs) and those differentially expressed in the tonsil plasma cell to bone marrow plasma cell transition were referred as “late differentiation genes” (LDGs). Previously defined and novel genes were identified that significantly discriminated tonsil B cells from tonsil plasma cells (359 genes) and tonsil plasma cells from bone marrow plasma cells (500 genes).

To classify multiple myeloma with respect to EDG and LDG, 74 newly diagnosed cases of multiple myeloma and 7 tonsil B cell, 7 tonsil plasma cell, and 7 bone marrow plasma cell samples were tested for variance across the 359 EDGs and 500 LDGs. The top 50 EDGs that showed the most significant variance across all samples were defined as early differentiation genes for myeloma (EDG-MM). Likewise, the top 50 LDGs showing the most significant variance across all samples were identified as late differentiation genes for myeloma-1 (LDG-MM1). Subtracting the LDG-MM1 from the 500 LDG and then applying one-way ANOVA test for variance to the remaining genes identified the top 50 genes showing similarities between bone marrow plasma cells and multiple myeloma. These genes were defined as LDG-MM2.

Hierarchical clustering was applied to all samples using 30 of the 50 EDG-MM. A total of 20 genes were filtered out with Max-Min<2.5. This filtering was performed on this group because many of the top 50 EDG-MM showed no variability across multiple myeloma and thus could not be used to distinguish multiple myeloma subgroups. A similar clustering strategy was employed to cluster the samples using the 50 LDG-MM1 and 50 LDG-MM2; however, in these cases all 50 significant genes were used in the cluster analysis.

EXAMPLE 4 RT-PCR and Immunohistochemistry

RT-PCR for the FGFR3 MMSET was performed on the same cDNAs used in the microarray analysis. Briefly, cDNA was mixed with the IGJH2 (5′-CAATGGTCACCGTCTCTTCA-3′, SEQ ID NO: 1) primer and the MMSET primer (5′-CCTCAATTTCCTGAAATTGGTT-3′, SEQ ID NO: 2). PCR reactions consisted of 30 cycles with a 58° C. annealing temperature and 1-minute extension time at 72° C. using a Perkin-Elmer GENEAMP 2400 thermocycler (Wellesley, Mass.). PCR products were visualized by ethidium bromide staining after agarose gel electrophoresis.

Immunohistochemical staining was performed on a VENTANA ES (Ventana Medical Systems, Tucson, Ariz.) using Zenker-fixed paraffin-embedded bone marrow sections, an avidin-biotin peroxidase complex technique (Ventana Medical Systems), and the antibody L26 (CD20, Ventana Medical Systems). Heat-induced epitope retrieval was performed by microwaving the sections for 28 minutes in a 1.0-mmol/L concentration of citrate buffer at pH 6.0.

EXAMPLE 5 Interphase FISH

For interphase detection of the t(11;14)(q13;q32) translocation fusion signal, a LSI IGH/CCND1 dual-color, dual-fusion translocation probe was used (Vysis, Inc, Downers Grove, Ill.). The TRI-FISH procedure used to analyze the samples has been previously described. Briefly, at least 100 clonotypic plasma cells identified by cIg staining were counted for the presence or absence of the translocation fusion signal in all samples except one, which yielded only 35 plasma cells. An multiple myeloma sample was defined as having the translocation when >25% of the cells contained the fusion.

EXAMPLE 6 Hierarchical Clustering of Plasma Cell Gene Expression Demonstrates Class Distinction

As a result of 656,000 measurements of gene expression in 118 plasma cell samples, altered gene expression in the multiple myeloma samples was identified. Two-dimensional hierarchical clustering differentiated cell types by gene expression when performed on 5,483 genes that were expressed in at least one of the 118 samples (FIG. 1A). The sample dendrogram derived two major branches (FIGS. 1A, 1D). One branch contained all 31 normal samples and a single monoclonal gammopathy of undetermined significance case whereas the second branch contained all 74 multiple myeloma and 4 monoclonal gammopathy of undetermined significance cases and the 8 cell lines. The multiple myeloma-containing branch was further divided into two sub-branches, one containing the 4 monoclonal gammopathy of undetermined significance and the other the 8 multiple myeloma cell lines. The cell lines were all clustered next to one another, thus showing a high degree of similarity in gene expression among the cell lines. This suggested that multiple myeloma could be differentiated from normal plasma cells and that at least two different classes of multiple myeloma could be identified, one more similar to monoclonal gammopathy of undetermined significance and the other similar to multiple myeloma cell lines.

Hierarchical clustering analysis with all 118 samples together with duplicate samples from 12 patients (plasma cells taken 24 hr or 48 hr after initial sample) were repeated to show reproducibility of the technique and analysis. All samples from the 12 patients studied longitudinally were found to cluster adjacent to one another. This indicated that gene expression in samples from the same patient were more similar to each other than they were to all other samples (data not shown).

In addition to the demonstration of reproducibility of clustering noted above, three microarray analyses were also performed on a single source of RNA from one patient. When included in the cluster analysis, the three samples clustered adjacent to one another. Consistent with the manufacturer's specification, an analysis of the fold changes seen in the samples showed that <2% of all genes had a >2-fold difference. Hence, these data indicated reproducibility for same samples.

The clustergram (FIG. 1A) showed that genes of unrelated sequence but similar function clustered tightly together along the vertical axis. For example, a particular cluster of 22 genes, primarily those encoding immunoglobulin molecules and major histocompatibility genes, had relatively low expression in multiple myeloma plasma cells and high expression in normal plasma cells (FIG. 1B). This was anticipated, given that the plasma cells isolated from multiple myeloma are clonal and hence only express single immunoglobulin light-chain and heavy-chain variable and constant region genes, whereas plasma cells from normal donors are polyclonal and express many different genes of these two classes. Another cluster of 195 genes was highly enriched for numerous oncogenes/growth-related genes (e.g., MYC, ABL1, PHB, and EXT2), cell cycle-related genes (e.g., CDC37, CDK4, and CKS2), and translation machinery genes (EIF2, EIF3, HTF4A, and TFIIA) (FIG. 1C). These genes were all highly expressed in MM, especially in multiple myeloma cell lines, but had low expression levels in normal plasma cells.

EXAMPLE 7 Hierarchical Clustering of Newly Diagnosed Multiple Myeloma Identifies Four Distinct Subgroups

Two-dimensional cluster analysis was performed on the 74 multiple myeloma cases alone. The sample dendrogram identified two major branches with two distinct subgroups within each branch (FIG. 1E). The four subgroups were designated MM1, MM2, MM3, and MM4 containing 20, 21, 15, and 18 patients respectively. The MM1 subgroup represented the patients whose plasma cells were most closely related to the monoclonal gammopathy of undetermined significance plasma cells and MM4 were most like the multiple myeloma cell lines (FIG. 1D). These data suggested that the four gene expression subgroups were authentic and might represent four distinct clinical entities.

Differences in gene expression across the four subgroups were then examined using the c² and WRS tests (Table 1). As expected the largest difference was between MM1 and MM4 (205 genes) and the smallest difference was between MM1 and MM2 (24 genes). Next, the top 30 genes turned on or upregulated in MM4 as compared with MM1 were examined (Table 2). The data demonstrated that 13 of 30 most significant genes (10 of the top 15 genes) were involved in DNA replication/repair or cell cycle control. Thymidylate synthase (TYMS), which was present in all 18 samples comprising the MM4 subgroup, was only present in 3 of the 20 MM1 samples and represented the most significant gene in the c² test. The DNA mismatch repair gene, mutS (E. coli) homolog 2 (MSH2) with a WRS p value of 2.8×10⁻⁶ was the most significant gene in the WRS test. Other notable genes in the list included the CAAX farnesyltransferase (FNTA), the transcription factors enhancer of zeste homolog 2 (EZH2) and MYC-associated zinc finger protein (MAZ), eukaryotic translation initiation factors (EIF2S1 and EIF2B1), as well as the mitochondrial translation initiation factor 2 (MTIF2), the chaperone (CCT4), the UDP-glucose pyrophosphorylase 2 (IUGP2), and the 26S proteasome-associated pad1 homolog (POH1).

To assess the validity of the clusters with respect to clinical features, correlations of various clinical parameters across the 4 subgroups were analyzed (Table 3). Of 17 clinical variables tested, the presence of an abnormal karyotype (p=0.0003) and serum b2M levels (p=0.0005) were significantly different among the four subgroups and increased creatinine (p=0.06) and cytogenetic deletion of chromosome 13 (p=0.09) were marginally significant. The trend was to have higher b2M and creatinine as well as an abnormal karyotype and chromosome 13 deletion in the MM4 subgroup as compared with the other 3 subgroups.

TABLE 1 Differences In Gene Expression Among Multiple Myeloma Subgroups Comparison Range of WRS* P Values Number of Genes MM1 vs MM4 .00097 to 9.58 × 10⁻⁷ 205 MM2 vs MM4 .00095 to 1.0410⁻⁶ 162 MM3 vs MM4 .00098 to 3.7510⁻⁶ 119 MM1 vs MM3 .00091 to 6.2710⁻⁶ 68 MM2 vs MM3 .00097 to 1.9810⁻⁵ 44 MM1 vs MM2 .00083 to 2.9310⁻⁵ 24 *Wilcoxon rank sum test. Comparisons are ordered based on the number of significant genes. Comparisons have a WRS P value < 0.001.

TABLE 2 The 30 Most Differentially Expressed Genes In A Comparison Of MM1 and MM4 Subgroups Gene MM1 MM4 Chi WRS^(‡) Accession Function Symbol (N = 20) (N = 18) Square p Value D00596 DNA replication TYMS 3 18 24.35 1.26 × 10⁻⁴ U35835 DNA repair PRKDC 2 17 23.75 4.55 × 10⁻⁶ U77949 DNA replication CDC6 1 13 15.62 5.14 × 10⁻⁶ U91985 DNA fragmentation DFFA 1 12 13.38 6.26 × 10⁻⁵ U61145 transcription EZH2 4 15 12.77 1.67 × 10⁻⁴ U20979 DNA replication CHAF1A 2 12 10.75 1.10 × 10⁻⁴ U03911 DNA repair MSH2 0 9 10.48 2.88 × 10⁻⁶ X74330 DNA replication PRIM1 0 9 10.48 9.36 × 10⁻⁶ X12517 SnRNP SNR PC 0 9 10.48 5.26 × 10⁻⁶ D85131 transcription MAZ 0 9 10.48 1.08 × 10⁻⁵ L00634 farnesyltransferase FNTA 10 18 9.77 7.28 × 10⁻⁵ U21090 DNA replication POLD2 11 18 8.27 8.05 × 10⁻⁵ X54941 cell cycle CKS1 10 17 7.07 1.26 × 10⁻⁴ U62136 cell cycle UBE2V2 13 18 5.57 4.96 × 10⁻⁶ D38076 cell cycle RANBP1 13 18 5.57 7.34 × 10⁻⁶ X95592 unknown C1D^(†) 13 18 5.57 1.10 × 10⁻⁴ X66899 cell cycle EWSR1 14 18 4.35 1.89 × 10⁻⁴ L34600 translation initiation MTIF2 14 18 4.35 3.09 × 10⁻⁵ U27460 Metabolism IUGP2 15 18 3.22 1.65 × 10⁻⁴ U15009 SnRNP SNRPD3 15 18 3.22 1.47 × 10⁻⁵ J02645 translation initiation EIF2S1 16 18 2.18 7.29 × 10⁻⁵ X95648 translation initiation EIF2B1 16 18 2.18 1.45 × 10⁻⁴ M34539 calcium signaling FKBP1A 18 18 0.42 1.71 × 10⁻⁵ J04611 DNA repair G22P1 18 18 0.42 7.29 × 10⁻⁵ U67122 anti-apoptosis UBL1 20 18 0.00 7.29 × 10⁻⁵ U38846 chaperon CCT4 20 18 0.00 1.26 × 10⁻⁴ U80040 metabolism ACO2 20 18 0.00 8.38 × 10⁻⁵ U86782 proteasome POH^(†) 20 18 0.00 5.90 × 10⁻⁵ X57152 signaling CSNK2B 20 18 0.00 7.29 × 10⁻⁵ D87446 unknown KIAA0257 20 18 0.00 1.26 × 10⁻⁵ Accession numbers listed are GENBANK numbers. ^(†)Gene symbol not HUGO approved. ^(‡)Wilcoxon rank sum test.

TABLE 3 Clinical Parameters Linked To Multiple Myeloma Subgroups Multiple Myeloma Subgroups Clinical Parameter 1 2 3 4 P value Abnormal cytogenetics 40.0% 5.3% 53.3% 72.2% .00028 Average b2-microglobulin 2.81 2.73 4.62 8.81 .00047 (mg/L) ANOVA, Chi square, and Fisher's exact tests were used to determine significance.

EXAMPLE 8 Altered Expression of 120 Genes in Malignant Plasma Cells

Hierarchical cluster analysis disclosed above showed that multiple myeloma plasma cells could be differentiated from normal plasma cells. Genes distinguishing the multiple myeloma from normal plasma cells were identified as significant by c² analysis and the WRS test (p<0.0001). A statistical analysis showed that 120 genes distinguished multiple myeloma from normal plasma cells. Pearson correlation analyses of the 120 differentially expressed genes were used to identify whether the genes were upregulated or downregulated in MM.

When genes associated with immune function (e.g. IGH, IGL, HLA) that represent the majority of significantly downregulated genes were filtered out, 50 genes showed significant downregulation in multiple myeloma (Table 4). The p values for the WRS test ranged from 9.80×10⁻⁵ to 1.56×10⁻¹⁴, and the c² test of the absence or presence of the expression of the gene in the groups ranged from 18.83 to 48.45. The gene representing the most significant difference in the c² test was the CXC chemokine SDF1. It is important to note that a comparison of multiple myeloma plasma cells to tonsil-derived plasma cells showed that, like multiple myeloma plasma cells, tonsil plasma cells also do not express SDF1. Two additional CXC chemokines, PF4 and PF4V1, were also absent in multiple myeloma plasma cells. The second most significant gene was the tumor necrosis factor receptor super family member TNFRF7 coding for CD27, a molecule that has been linked to controlling maturation and apoptosis of plasma cells.

The largest group of genes, 20 of 50, were linked to signaling cascades. multiple myeloma plasma cells have reduced or no expression of genes associated with calcium signaling (S100A9 and S100A12) or lipoprotein signaling (LIPA, LCN2, PLA2G7, APOE, APOC1). LCN2, also known as 24p3, codes for secreted lipocalin, which has recently been shown to induce apoptosis in pro B-cells after growth factor deprivation. Another major class absent in multiple myeloma plasma cells was adhesion-associated genes (ITGA2B, IGTB2, GP5, VCAM, and MIC2).

Correlation analysis showed that 70 genes were either turned on or upregulated in multiple myeloma (Table 5). When considering the c² test of whether expression is present or absent, the cyclin-dependent inhibitor, CDKN1A, was the most significantly differentially expressed gene (c²=53.33, WRS=3.65×10⁻¹¹). When considering a quantitative change using the WRS test, the tyrosine kinase oncogene ABL1 was the most significant (c²=43.10, WRS=3.96×10⁻¹⁴). Other oncogenes in the list included USF2, USP4, MLLT3 and MYC. The largest class of genes represented those whose products are involved in protein metabolism (12 genes), including amino acid synthesis, translation initiation, protein folding, glycosylation, trafficking, and protein degradation. Other multiple-member classes included transcription (11 genes), signaling (9 genes), DNA synthesis and modification (6 genes), and histone synthesis and modification (5 genes).

Overexpression of signaling genes such as QSCN6, PHB, phosphatases PTPRK and PPP2R4, and the kinase MAPKAPK3 has been linked to growth arrest. The only secreted growth factor in the signaling class was HGF, a factor known to play a role in multiple myeloma biology. The MOX2 gene, whose product is normally expressed as an integral membrane protein on activated T cells and CD19⁺ B cells and involved in inhibiting macrophage activation, was in the signaling class. The tumor suppressor gene and negative regulator of b-catenin signaling, APC, was another member of the signaling class. Classes containing two members included RNA binding, mitochondrial respiration, cytoskeletal matrix, metabolism, cell cycle, and adhesion. Single member classes included complement cascasde (MASP1), drug resistance (MVP), glycosaminoglycan catabolism heparin sulfate synthesis (EXTL2), and vesicular transport (TSC1). Four genes of unknown function were also identified as significantly upregulated in MM.

TABLE 4 The 45 Most Significantly Downregulated Genes In Multiple Myeloma In Comparison With Normal Bone Marrow Plasma Cells Gene Chi WRS ^(‡) Accession Function Symbol Square p value L36033 cxc chemokine SDF1 48.45 3.05 × 10⁻¹² M63928 signaling TNFRSF7 48.45 6.35 × 10⁻¹¹ U64998 ribonuclease RNASE6 46.44 2.82 × 10⁻⁹  M20902 lipoprotein signaling APOC1 45.62 4.63 × 10⁻¹⁰ M26602 immunity DEFA1 40.75 1.06 × 10⁻¹² M21119 immunity LYZ 40.73 6.24 × 10⁻¹⁰ M14636 metabolism PYGL 39.84 1.15 × 10⁻¹⁰ M26311 calcium signaling S100A9 38.96 3.60 × 10⁻¹³ M54992 signaling CD72 36.14 2.40 × 10⁻⁹  X16832 protein degradation CTSH 35.26 1.81 × 10⁻¹² M12529 lipoprotein signaling APOE 34.50 3.95 × 10⁻¹⁴ M15395 adhesion ITGB2 34.02 1.74 × 10⁻¹³ Z74616 extracellular matrix COL1A2 34.02 8.06 × 10⁻¹¹ HT2152 receptor signaling CD163 33.01 1.66 × 10⁻¹² U97105 pyrimidine metabolism DPYSL2 32.52 2.22 × 10⁻¹⁰ U81787 signaling WNT10B 32.50 1.77 × 10⁻⁵  HT3165 receptor tyrosine AXL 31.36 5.26 × 10⁻¹¹ kinase M83667 transcription CEBPD 31.19 4.69 × 10⁻¹⁰ L33930 receptor signaling CD24 30.33 1.56 × 10⁻¹⁴ D83657 calcium signaling S100A12 29.91 6.58 × 10⁻⁸  M11313 proteinase inhibitor A2M 29.91 1.07 × 10⁻¹⁰ M31158 signaling PRKAR2B 29.91 2.20 × 10⁻⁹  U24577 lipoprotein signaling PLA2G7 29.78 2.08 × 10⁻¹⁰ M16279 adhesion MIC2 28.75 8.01 × 10⁻¹¹ HT2811 cell cycle CDK8 28.32 6.53 × 10⁻⁹  M26167 cxc chemokine PF4V1 27.35 4.68 × 10⁻¹¹ U44111 metabolism HNMT 27.24 2.07 × 10⁻¹¹ X59871 transcription TCF7 26.79 7.16 × 10⁻¹⁰ X67235 transcription HHEX 25.21 2.07 × 10⁻¹⁰ U19713 calcium signaling AIF1 25.21 2.57 × 10⁻¹⁰ Y08136 apoptosis ASM3A ^(†) 24.74 3.30 × 10⁻⁸  M97676 transcription MSX1 24.58 9.80 × 10⁻⁵  M64590 house keeping GLDC 24.27 4.10 × 10⁻⁸  M20203 protease ELA2 24.03 6.36 × 10⁻¹² M30257 adhesion VCAM1 23.42 1.71 × 10⁻¹⁰ M93221 mediates endocytosis MRC1 23.30 1.15 × 10⁻⁷  S75256 lipoprotein signaling LCN2 23.30 4.17 × 10⁻⁷  U97188 RNA binding KOC1 ^(†) 22.47 5.86 × 10⁻⁹  Z23091 adhesion GP5 22.47 7.58 × 10⁻⁷  M34344 adhesion ITGA2B 21.99 8.00 × 10⁻⁸  M25897 cxc chemokine PF4 21.89 1.12 × 10⁻⁸  M31994 house keeping ALDH1A1 21.36 4.86 × 10⁻⁹  Z31690 lipoprotein signaling LIPA 20.67 1.50 × 10⁻⁹  S80267 signaling SYK 20.42 5.90 × 10⁻⁵  U00921 signaling LY117 18.83 1.57 × 10⁻⁸  Accession numbers listed are GENBANK numbers, except those beginning with “HT”, which are provided by the Institute of Genomic Research (TIGR). ^(†) Gene symbol not HUGO approved. ^(‡) Wilcoxon rank sum test.

TABLE 5 The 70 Most Significantly Upregulated Genes in Multiple Myeloma in Comparison with Normal Bone Marrow Plasma Cells Gene Chi WRS ^(‡) Accession Function Symbol ^(†) Square p Value U09579 cell cycle CDKN1A 53.33  3.65 × 10⁻¹¹ U78525 amino acid synthesis EIF3S9 49.99  2.25 × 10⁻¹² HT5158 DNA synthesis GMPS 47.11  4.30 × 10⁻¹² X57129 histone H1F2 46.59  5.78 × 10⁻¹³ M55210 adhesion LAMC1 45.63 1.34 × 10⁻⁹ L77886 signaling, phosphatase PTPRK 45.62  5.42 × 10⁻¹⁰ U73167 glycosaminoglycan HYAL3 44.78  1.07 × 10⁻¹⁰ catabolism X16416 oncogene, kinase ABL1 43.10  3.96 × 10⁻¹⁴ U57316 transcription GCN5L2 43.04  1.36 × 10⁻¹² Y09022 protein glycosylation NOT56L ^(†) 42.05  5.53 × 10⁻¹⁰ M25077 RNA binding SSA2 41.26 1.69 × 10⁻⁷ AC002115 mitochondrial respiration COX6B 41.16 2.16 × 10⁻⁸ Y07707 transcription NRF ^(†) 37.59  4.79 × 10⁻¹⁰ L22005 protein ubiquination CDC34 34.50 2.89 × 10⁻⁶ X66899 transcription EWSR1 34.39 4.23 × 10⁻⁸ D50912 RNA binding RBM10 33.93 2.61 × 10⁻⁶ HT4824 amino acid synthesis CBS 33.77 1.49 × 10⁻⁶ U10324 transcription ILF3 33.33  3.66 × 10⁻¹¹ AD000684 oncogene, transcription USF2 32.18  7.41 × 10⁻¹¹ U68723 cell cycle CHES1 31.68 1.03 × 10⁻⁶ X16323 signaling, growth factor HGF 30.67 4.8210⁻⁹ U24183 metabolism PFKM 30.47  8.92 × 10⁻¹⁰ D13645 unknown KIAA0020 ^(†) 30.47 7.40 × 10⁻⁶ S85655 signaling, growth arrest PHB 29.37 1.32 × 10⁻⁸ X73478 signaling, phosphatase PPP2R4 28.32 6.92 × 10⁻⁹ L77701 mitochondrial respiration COX17 27.81 1.33 × 10⁻⁶ U20657 oncogene, proteasome USP4 27.71 2.31 × 10⁻⁶ M59916 signaling, DAG signaling SMPD1 27.49 3.52 × 10⁻⁸ D16688 oncogene, DNA binding MLLT3 27.24  6.97 × 10⁻¹³ X90392 DNA endonuclease DNASE1L1 26.98 4.72 × 10⁻⁷ U07424 amino acid synthesis FARSL 26.93 1.66 × 10⁻⁶ X54199 DNA synthesis GART 26.57  9.61 × 10⁻¹¹ L06175 unknown P5-1 ^(†) 26.57 5.16 × 10⁻⁷ M55267 unknown EVI2A 25.92 3.79 × 10⁻⁶ M87507 protein degradation CASP1 25.78 5.46 × 10⁻⁷ M90356 transcription BTF3L2 25.78 9.68 × 10⁻⁸ U35637 cytoskeletal matrix NEB 25.40 9.15 × 10⁻⁶ L06845 amino acid synthesis CARS 25.34 5.39 × 10⁻⁸ U81001 DNA, nuclear matrix SNURF 24.58 4.54 × 10⁻⁵ attachment U76189 heparan sulfate synthesis EXTL2 24.58 7.28 × 10⁻⁶ U53225 protein trafficking SNX1 24.48 5.53 × 10⁻⁷ X04366 protein degradation CAPN1 24.35 1.26 × 10⁻⁹ U77456 protein folding NAP1L4 24.27  4.23 × 10⁻¹⁰ L42379 signaling, growth arrest QSCN6 24.27  1.28 × 10⁻¹⁰ U09578 signaling, kinase MAPKAPK3 24.27 2.35 × 10⁻⁹ Z80780 histone H2BFH 24.27  3.44 × 10⁻¹² HT4899 oncogene, transcription MYC 24.27 1.77 × 10⁻⁵ M74088 signaling, b-catenin APC 23.94 1.50 × 10⁻⁵ regulator X57985 histone H2BFQ 23.90  3.25 × 10⁻¹² X79882 drug resistance MVP 23.47  1.77 × 10⁻¹¹ X77383 protein degradation CTSO 23.18 4.68 × 10⁻⁷ M91592 transcription ZNF76 23.16 1.12 × 10⁻⁸ X63692 DNA methyltransferase DNMT1 23.12  5.15 × 10⁻¹¹ M60752 histone H2AFO 21.60 1.46 × 10⁻⁸ M96684 transcription PURA 21.25 4.54 × 10⁻⁵ U16660 metabolism ECH1 21.18 5.52 × 10⁻⁵ M86737 DNA repair SSRP1 20.60 2.62 × 10⁻⁵ U35113 histone deacetylase MTA1 20.60  6.67 × 10⁻¹⁰ X81788 unknown ICT1 20.42 2.97 × 10⁻⁷ HT2217 signaling MUC2A 20.33 2.61 × 10⁻⁷ M62324 unknown MRF-1 ^(†) 20.31 3.98 × 10⁻⁹ U09367 transcription ZNF136 20.30 7.72 × 10⁻⁹ X89985 cytoskeletal matrix BCL7B 19.81 5.50 × 10⁻⁹ L19871 transcription repression ATF3 19.43 1.13 × 10⁻⁶ X69398 adhesion CD47 19.16 6.44 × 10⁻⁷ X05323 Signaling MOX2 19.16 8.58 × 10⁻⁶ macrophage inhibitor X04741 protein ubiquination UCHL1 19.14 9.76 × 10⁻⁵ D87683 vesicular transport TSC1 19.12 6.81 × 10⁻⁶ D17525 complement cascade MASP1 18.81 4.05 × 10⁻⁷ Accession numbers listed are GENBANK numbers, except those beginning with “HT”, which are provided by the Institute of Genomic Research (TIGR). ^(†) Gene symbol not HUGO approved. ^(‡) Wilcoxon rank sum test.

EXAMPLE 9

Altered Expression of 14 Genes Differentiates Malignant from Normal Plasma Cells

The present invention also sought to determine whether expression patterns of a minimum number of genes could be used to clearly differentiate normal, pre-neoplastic and malignant plasma cells. A multivariate step-wise discriminant analysis (MSDA) was applied to the top 50 significantly differentially expressed genes across the normal plasma cells (N=26) and multiple myeloma plasma cells (N=162) and a linear discriminant function between the normal plasma cell group and multiple myeloma group was observed. Both forward and backward variable selections were performed. The choice to enter or remove variables was based on a Wilks' λ analysis, defined as follows: λ(x)=det W(x)/det T(x) where W(x) and T(x) are the within-group and total scatter matrices respectively. Wilks' λ can assume values ranging from 0 to 1. The significance of change in λ was tested using the F statistic. At the end of multivariate step-wise discriminant analysis, only 14 genes were selected to compute the canonical discriminant functions (Table 6). The multivariate step-wise discriminant analysis selected the following equation: Discriminant score=HG4716×3.683−L33930×3.134+L42379×1.284+L77886×1.792+M14636×5.971−M26167×6.834+U10324×2.861−U24577×10.909+U35112×2.309+X16416×6.671−X64072×5.143+79822×5.53+Z22970×4.147+Z80780×2.64−87.795. The cutoff value was −3.3525. Values less than −3.3525 indicated the sample belonged to the normal group and values greater than −3.3525 indicated the sample belonged to the multiple myeloma group.

The 14 gene model was then applied to a training group consisting of 162 multiple myeloma and 26 normal plasma cell (data not shown). A cross-validation analysis was performed where samples were removed one at a time from the sample set, and training statistics and expression means for each class of the modified sample set were re-calculated. A predictive value using genes with a p value<0.05 in the modified sample set was generated. A 100% accurate prediction of the sample types in the training group was obtained.

A validation group was then applied to the model. The multivariate step-wise discriminant analysis correctly classified 116 of 118 (98.31%) primary multiple myeloma samples and 8 of 8 (100%) of human myeloma cell lines as multiple myeloma. In addition, 6 of 6 normal plasma plasma cell samples were classified as normal. Importantly, the model predicted that 6 of 7 monoclonal gammopathy of undetermined significance cases were multiple myeloma with 1 monoclonal gammopathy of undetermined significance case predicted to be normal (FIG. 5). The classification of the 6 monoclonal gammopathy of undetermined significance cases as multiple myeloma has important ramifications in that it suggests that cells in this benign condition have strong similarities to fully transformed cells. These results also have important implications in the etiology of monoclonal gammopathy of undetermined significance and its transition to overt multiple myeloma. The fact that the model classified monoclonal gammopathy of undetermined significance as multiple myeloma is consistent with recent studies that have shown monoclonal gammopathy of undetermined significance has chromosomal abnormalities e.g. translocations of the IGH locus and deletion of chromosome 13 that are also common in multiple myeloma. Future studies will be aimed at identification of gene expression patterns that can actually distinguish monoclonal gammopathy of undetermined significance from multiple myeloma. With the majority of the monoclonal gammopathy of undetermined significance cases being classified as multiple myeloma, the classification of a 1 monoclonal gammopathy of undetermined significance cases as normal may indicate 1) the patient does not have monoclonal gammopathy of undetermined significance or 2) the monoclonal gammopathy of undetermined significance cells represented a minority of the plasma cells in the sample. The monoclonal gammopathy of undetermined significance case and the 2 multiple myeloma cases classified as normal will be followed longitudinally to determine whether in the future the samples will shift to the multiple myeloma group.

In order to further validate the discriminant results, two-dimensional hierarchical clustering was performed on 927 genes with expression in at least one sample. The 118 multiple myeloma samples from the validation group, 32 normal plasma cells, 7 multiple myeloma cell lines, and 7 monoclonal gammopathy of undetermined significance were studied. Along the horizontal axis, experimental samples were arranged such that those with the most similar patterns of expression across all genes were placed adjacent to each other. Surprisingly, the two misclassified multiple myelomas and one monoclonal gammopathy of undetermined significance classified as normal plasma samples by discriminant analysis were also connected to the normal group in the cluster analysis (FIGS. 6A-6B). This result indicated that the 14 gene discriminant model was consistent with a 927 gene hierarchical cluster model.

A survey of the function of the 14 genes in the above analysis showed several interesting features. The genes are not related in function and thus represent unique and independent genetic markers that can clearly be used as signatures of normal and malignant cells. Genes are associated with the microenvironment (ITGB2), cell transformation (ABL1) and drug resistance (MVP). It is possible that the deregulated expression of these genes may represent fundamental genetic abnormalities in the malignant transformation of plasma cells. For example, the ITGB2 gene encodes the glycoprotein b-2 integrin (CD18) which is critical to the formation of integrin heterodimers known to mediate cell-cell and/or cell-matrix adhesion events. As plasma cells constitutively express ICAM-1 and this molecule can be induced on bone marrow adherent cells, one can envisage a mechanism in which the ITGB2/ICAM-1 adhesion pathway mediates adhesion among plasma cells as well as with cells in the bone marrow microenvironment. In human lymphomas, ITGB2 expression is found on tumor cells in low- and medium-grade malignant lymphomas, whereas absence of ITGB2 seems to be a characteristic of high-grade malignant lymphomas. Similar to other B lymphoma, the absence of ITGB2 might contribute to an escape from immunosurveillance in multiple myeloma.

In summary, the present invention describes a model that makes it possible to diagnosis multiple myeloma by the use of the differential expression of 14 genes. It is currently not clear whether deregulated expressions of these genes are involved in the creation of the malignant phenotype or whether they represent sentinels of some underlying yet to be recognized genetic defect(s). However, the functions of these genes suggest an underlying causal relationship between the deregulated expression and malignancy.

TABLE 6 Fourteen Gene Defining a Diagnosis Model for Multiple Myeloma Gene Wilks' F to Accession* Symbol Lambda Remove p number HT5158 GMPS 0.090 10.99 0.0011 L33930 CD24 0.089 8.80 0.0034 L42379 QSCN6 0.087 4.24 0.0409 L77886 PTPRK 0.088 6.46 0.0119 M14636 PYGL 0.091 12.62 0.0005 M26167 PF4V1 0.091 12.39 0.0005 U10324 ILF3 0.090 11.98 0.0007 U24577 PLA2G7 0.107 44.28  3.23 × 10⁻¹⁰ U35113 MTA1 0.088 6.22 0.0135 X16416 ABL1 0.099 27.65 4.04 × 10⁻⁷ X64072 ITGB2 0.097 24.63 1.59 × 10⁻⁶ X79882 MVP 0.098 25.83 9.19 × 10⁻⁷ Z22970 CD163 0.088 6.08 0.0146 Z80780 H2B 0.092 14.58 0.0002 *Accession number listed are GENBANK numbers, except the one that begin with “HT”, which is provided by the Institute of Genomic Research.

EXAMPLE 10 Differential Expression of 24 Genes Can Accurately Differentiate Gene Expression-Defined Subgroups of Multiple Myeloma

The present invention also sought to determine whether expression patterns of a minimum number of genes could be used to clearly differentiate the gene expression-defined subgroups of multiple myeloma identified with hierarchical clustering of over 5,000 genes. As discussed above, two-dimensional cluster analysis of 263 multiple myeloma cases, 14 normal plasma cells, 7 MGUS and 7 multiple myeloma cell lines was performed. The sample dendrogram showed four subgroups of MM1, MM2, MM3 and MM4 containing 50, 75, 67, and 71 patients respectively. Then, the top 120 statistically significant differentially expressed genes as determined by Chi-square and Wilcoxon test of 31 normal plasma cells and 74 newly diagnosed multiple myeloma were chosen for use in a canonical discriminant analysis. By applying a linear regression analysis 24 genes were defined as predictors able to differentiate the multiple myeloma subgroups (Table 7).

The 24 genes predictor model was applied to a training group consisting of multiple myeloma plasma cell samples located in the center of each hierarchical clustering group [total N=129; MM1=23, MM2=33, MM3=34 and MM4=39]. A cross-validation analysis was performed on the training group where samples were removed one at a time from the sample set, and training statistics and expression means for each class of the modified sample set were re-calculated. A predictive value using genes with a p value<0.05 in the modified sample set was generated. The results of this analysis showed that a 100% accurate prediction of the sample types in the training group was obtained. A validation group was then applied to the model. The multivariate step-wise discriminant analysis correctly classified 116 of 134 (86.56%) primary multiple myeloma samples into different subgroups as compared with the subgroups defined by hierarchical clustering. Importantly, 7 of 7 (100%) of human myeloma cell lines were classified to MM4 as expected. In addition, the model predicted that 5 of 7 MGUS cases were MM1, and the remaining cases were predicted to be MM2 and MM3 respectively (FIG. 7).

TABLE 7 Twenty-Four Genes Defining Subgroups of Multiple Myeloma Gene Wilks’ F to Accession No. Symbol Lambda Remove p value X54199 GART 0.004 3.13 0.0791 M20902 APOC1 0.005 4.05 0.0462 X89985 BCL7B 0.005 4.47 0.0365 M31158 PRKAR2B 0.005 5.07 0.0260 U44111 HNMT 0.005 5.68 0.0186 X16416 ABL1 0.005 6.72 0.0106 HT2811 NEK2 0.005 8.35 0.0045 D16688 MLLT3 0.005 8.36 0.0045 U57316 CCN5L2 0.005 8.49 0.0042 U77456 NAP1L4 0.005 8.57 0.0040 D13645 KIAA00 0.005 9.17 0.0030 M64590 GLDC 0.005 9.92 0.0020 L77701 COX17 0.005 10.01 0.0019 U20657 USP4 0.005 11.10 0.0011 L06175 P5-1 0.005 11.11 0.0011 M26311 S100A9 0.005 11.20 0.0011 X04366 CAPN1 0.005 11.67 0.0009 AC002115 COX6B 0.006 13.64 0.0003 X06182 C-KIT 0.006 13.72 0.0003 M16279 MIC2 0.006 16.12 0.0001 M97676 MSX1 0.006 16.41 0.0001 U10324 LIF3 0.006 19.66 0.0000 S85655 PHB 0.007 20.63 0.0000 X63692 DNMT1 0.007 21.53 0.0000 Accession number listed are GENBANK numbers, except the one that begin with “HT”, which is provided by the Institute of Genomic Research.

EXAMPLE 11 Gene Expression “Spikes” in Subsets of Multiple Myeloma

A total of 156 genes not identified as differently expressed in the statistical analysis of multiple myeloma versus normal plasma cells, yet highly overexpressed in subsets of multiple myeloma, were also identified. A total of 25 genes with an AD spike greater than 10,000 in at least one sample are shown (Table 8). With 27 spikes, the adhesion associated gene FBLN2 was the most frequently spiked. The gene for the interferon induced protein 27, IFI27, with 25 spikes was the second most frequently spiked gene and contained the highest number of spikes over 10,000 (N=14). The FGFR3 gene was spiked in 9 of the 74 cases (FIG. 2A). It was the only gene for which all spikes were greater than 10,000 AD. In fact, the lowest AD value was 18,961and the highest 62,515, which represented the highest of all spikes. The finding of FGFR3 spikes suggested that these spikes were induced by the multiple myeloma-specific, FGFR3-activating t(4;14)(p21;q32) translocation. To test the above hypothesis, RT-PCR for a t(4;14)(p21;q32) translocation-specific fusion transcript between the IGH locus and the gene MMSET was performed (data not shown). The translocation-specific transcript was present in all 9 FGFR3 spike samples but was absent in 5 samples that did not express FGFR3. These data suggested that the spike was caused by the t(4;14)(p21;q32) translocation.

The CCND1 gene was spiked with AD values greater than 10,000 in 13 cases. TRI-FISH analysis for the t(11;14)(q13;q32) translocation was performed (Table 9). All 11 evaluable samples were positive for the t(11;14)(q13;q32) translocation by TRI-FISH; 2 samples were not analyzable due to loss of cell integrity during storage. Thus, all FGFR3 and CCND1 spikes could be accounted for by the presence of either the t(4;14)(p21I;q32) translocation or the t(11;14)(q13;q32) translocation respectively.

Next, the distribution of the FGFR3, CST6, IFI27, and CCND1 spikes within the gene expression-defined multiple myeloma subgroups was determined (FIGS. 2A-2D). The data showed that FGFR3 and CST6 spikes were more likely to be found in MM1 or MM2 (p<0.005) whereas the spikes for IFI27 were associated with an MM3 and MM4 distribution (p<0.005). CCND1 spikes were not associated with any specific subgroup (p>0.1). It is noteworthy that both CST6 and CCND1 map to 11q13 and had no overlap in spikes. It remains to be tested whether CST6 overexpression is due to a variant t(11;14)(q13;q32) translocation. The five spikes for MS4A2 (CD20) were found in either the MM1 (3 spikes) or MM2 (2 spikes) subgroups (data not shown).

The gene MS4A2 which codes for the CD20 molecule was also found as a spiked gene in four cases (FIG. 3A). To investigate whether spiked gene expression correlated with protein expression, immunohistochemistry for CD20 was performed on biopsies from 15 of the 74 multiple myeloma samples (FIG. 3B). All four cases that had spiked MS4A2 gene expression were also positive for CD20 protein expression, whereas 11 that had no MS4A2 gene expression were also negative for CD20 by immunohistochemistry. To add additional validation to the gene expression profiling, a comparison of CD marker protein and gene expression in the multiple myeloma cell line CAG and the EBV-transformed lymphoblastoid cell line ARH-77 were also performed (FIGS. 4A-4B). The expression of CD138 and CD38 protein and gene expression was high in CAG but absent in ARH-77 cells. On the other hand, expression of CD19, CD20, CD21, CD22, CD45, and CDw52 was found to be strong in ARH-77 and absent in CAG cells. The nearly 100% coincidence of FGFR3 or CCND1 spiked gene expression with the presence of the t(4;14)(p14;q32) or t(11;14)(q13;q32) translocation; the strong correlation of CD20 and MS42A gene expression in primary multiple myeloma; and strong correlation of CD marker protein and gene expression in B cells and plasma cells represent important validations of the accuracy of the gene expression profiling disclosed herein.

TABLE 8 Genes with “Spiked” Expression in Plasma Cells from Newly Diagnosed Multiple Myeloma Patients # of Accession No. Function Gene Symbol Spikes Spikes >10K Max Spike M64347 signaling FGFR3 9 9 62,515 U89922 immunity LTB 4 2 49,261 X67325 interferon signaling IFI27 25 14 47,072 X59798 cell cycle CCND1 6 13 42,814 U62800 cysteine protease inhibitor CST6 17 6 36,081 U35340 eye lens protein CRYBB1 4 1 35,713 X12530 B-cell signaling MS4A2 5 5 34,487 X59766 unknown AZGP1 18 4 28,523 U58096 unknown TSPY 4 1 23,325 U52513 interferon signaling IFIT4 5 2 21,078 X76223 vesicular trafficking MAL 19 5 20,432 X92689 O-linked glycosylation GALNT3 4 1 18,344 D17427 adhesion DSC3 8 7 17,616 L11329 signaling DUSP2 14 1 15,962 L13210 adhesion, macrophage. lectin LGALS3BP 8 2 14,876 U10991 unknown G2^(†) 7 1 14,815 L10373 integral membrane protein TM4SF2 4 2 14,506 U60873 unknown 137308 12 1 12,751 M65292 complement regulation HFL1 9 1 12,718 HT4215 phospholipid transport PLTP 23 1 12,031 D13168 growth factor receptor ENDRB 18 1 11,707 AC002077 signaling GNAT1 21 1 11,469 M92934 growth factor CTGF 4 1 11,201 X82494 adhesion FBLN2 27 7 10,648 M30703 growth factor AR 5 1 10,163 Accession numbers listed are GENBANK numbers, except those beginning with “HT”, which are provided by the Institute of Genomic Research (TIGR). ^(†)Gene symbol not HUGO approved.

TABLE 9 Correlation of CCND1 Spikes with FISH-Defined t(11; 14)(q13; q32) GC CCND1 Spike FISH Percent PCs with Cells PT* (AD value)^(†) t(11; 14) Translocation Counted P168 42,813 Yes 59% 113 P251 33,042 Yes 80% 124 P91 31,030 Not done — — P99 29,862 Yes 65% 111 P85 26,737 Yes 92% 124 P241 25,611 Yes 96% 114 P56 23,654 Yes 100%  106 P63 22,358 Yes 98% 104 P199 18,761 Yes 60% 35 P107 15,205 Yes 100%  147 P75 14,642 Yes 100%  105 P187 14,295 Yes 25% 133 P124 10,594 Not done — — *GC PT = patient identifier; ^(†)AD = average difference call.

EXAMPLE 12 A 15-Gene Model Representing Seven Subgroups of Multiple Myeloma

In the present example, feature-subset selection was used to extract genes relevant to specific myeloma subtypes. In this regard, multivariate stepwise discriminant analysis (MSDA) was applied and identified 15 genes that could correctly separate tissue samples into seven subtypes. This small, subtle set of genes gave a final prediction accuracy of more than 92% and 95% in a training and an independent testing sets, respectively. Examining the expression of the 15 genes identified here not only would provide important new insights into the diagnosis and pathogenesis of these myeloma subtypes but also may pinpoint useful targets against which novel therapeutic agents could be developed.

Identification of Myeloma Subtypes

Samples from patients with newly diagnosed multiple myeloma (n=351) were studied by microarray analysis. Plasma cell isolation, RNA extraction, and hybridization to GENBANK U133 Plus 2.0 (Affymetrix) Arrays with 35,000 unique genes were performed as described previously (1, 3). All data used in the following analyses were derived with the AFFYMETRIX Microarray Suite (MAS) 5.0 software. AFFYMETRIX signal call was transformed by log base 2 and normalized to give a mean of 0 and variance of 1 for each sample.

The software package SPSS 11.0 (SPSS Inc.) and the significance analysis of microarrays (SAM) method were used for statistical analysis (4). Genes were selected for analysis on the basis of detection and false discovery rate. In each comparison, genes having “present” detection calls in more than one-third of the samples in the overexpressed gene group or a chi-square value>3.84 (p<0.5) were retained for statistical analysis. For two-class and multiclass supervised analyses, the SAM method was used with sample-label permutations to evaluate statistical significance. Student's t test and the chi-square test were performed to identify survival-related genes.

Hierarchic clustering or average linkage clustering with the centered correlation metric was employed (5). A total of 2,856 probe sets were scanned across 177 myeloma patients in the training set. The 2,856 probe sets across all samples were derived from 57,000 sets by filtering out all genes with “absent” detection calls and genes not fulfilling the test of standard deviation>0.6 (0.6 being the normalized signal).

For class-prediction analysis, we used the software tool called Prediction Analysis for Microarrays (PAM) in R version 1.7.1 (6). The method of the nearest shrunken centroid identified a subgroup of genes that best characterized a predefined class. The prediction error was calculated by means of 10-fold cross-validation within the training set followed by the use of a second validation set (almost one-half of the patients). Multivariate analysis based on stepwise multiple linear discriminant analysis (MSDA) with the Wilks lambda criterion was used to select the best combination of genes that differentiated myeloma subgroups. FIG. 8 shows the overview of the strategy used to classify and validate myeloma subgroups based on gene expression profiles. FIG. 9 shows the results of hierarchic cluster analysis of myeloma samples. The dendrogram of the 177 cases at the top of the matrix, in which the pattern and length of branches reflect the relatedness of the samples, indicates that the samples are clustered into seven branches on the basis of similar gene expression profiles.

Distinct Subtypes Associated with Recurrent Translocations

The distribution of spikes of FGFR3/MMSET, MAF, MAFB, CCND1, and CCND3 within the myeloma subgroups described above was determined. These genes are known as the most translocation-related genes in the 177-sample training set (FIGS. 10A-10D). Myeloma samples exhibiting one of the five spikes accounted for 40% of the total.

To determine chromosome 14q32 translocation, triple-color interphase FISH (TRI-FISH) protocol as described (7-8) was followed, and an LSI® IGH dual-color, break-apart rearrangement probe (Vysis Inc.) was used. This probe is a mixture of two probes that hybridize to opposite sides of the J segment through constant regions of the IgH locus. Approximately 900-kb SpectrumGreen™-labeled LSI® IGH probe covers essentially the entire IgH variable region. The hybridization target of approximately 250-kb SpectrumOrange™-labeled LSI® IGH 3′ flanking probe lies completely 3′ to the IgH locus. As a result of this probe design, any translocation with a breakpoint at the J segment or within switch sequences produced separate orange and green signals. For the purpose of this analysis, 14q required split IgH signal in at least 20% of approximately 100 Ig light chain-restricted clonal plasma cells.

With the use of TRI-FISH and four different probe combinations of VH/CH, disassociation of the VH from the CH probes was observed in 100of MAF/MAFB, 100% (15/15) of CCND1, and 100% (5/5) of CCND3 spike samples. In view of the exact correlation of spikes with the translocations, all 24 MMSET, 5 MAF, 5 MAFB, 34 CCND1,and 4 CCND3 spikes could be accounted for by the presence, respectively, of the t(4;14)(p21;q32), t(14;16)(q32;q23), t(14;20)(q32;q13), t(11;14)(q13;q32), and t(6;14)(p21;q32) translocations. With the exception of the CCND3 spike, which was randomly distributed among subgroups, the other spikes were clearly clustered together.

CCND1-IgH. Thirty (88%) of 34 myeloma samples with a CCND1 spike, which was caused by t(11;14)(q13;q32), were grouped in cluster III (FIG. 10A). Five specimens in this cluster did not show a spike. SAM and chi-square analysis revealed that CCND1 was the most discriminative gene for this cluster (14-fold increase). Interestingly, two early-B-cell factor target genes, VPREB3 and CD20, were highly correlated with this cluster (rank numbers 2 and 7 by mean ratio, respectively), perhaps because of increased expression of PAX5 with CCND1 activation.

MMSET-IgH or FGFR3-IgH. In group VII, 92% (22/24) of cases involved myeloma with t(4;14)(p21;q32) (FIG. 10A). Two specimens in this cluster showed neither a FGFR3 or an MMSET spike, but TRI-FISH for Ig heavy chain revealed a disassociation of VH from the CH probes. SAM and chi-square analysis showed that genes for Krüppel-like factor 4 (KLF4) and desmoglein 2 (DSG2) were extremely up-regulated in this class, whereas the Wnt-signaling antagonist FRZB and transcription factor ISL2 were the most down-regulated genes in this group.

MAF-IgH and MAFB-IgH. All five MAFB spikes representing t(14;20)(q32;q13) and five of six MAF spikes representing t(14;16)(q32;q23) were included in group V. SAM and chi-square analysis demonstrated a strong up-regulation of Toll-like-receptor 4 (TLR4), chemokine (C-X3-C motif) receptor 1(CX3CR1), osteopontin (SPP1), and CCND2 genes. The activation of CX3CR1 in mast cells was identified via TLR4 signaling; the high correlation probably suggests that cell-cycle-control gene CCND2 and tumor adhesion- and metastasis-associated gene SPP1 were activated through TLR4 signaling by MAF or MAFB activation.

Distinct Subtypes Associated with Cytogenetic Abnormality

Cytogenetic abnormality was observed in 33% (51/153) of patients; 67% of patients with multiple myeloma had normal karyotype. Of the 51 patients with a cytogenetic abnormality, 29 (57%) had hyperdiploidy and 22 (43%) hypodiploidy. Group IV contained most of the cases of myeloma with cytogenetic abnormality (76%). SAM and chi-square analysis revealed that genes controlling cell cycle, such as CCNB2, CCNB1, MCM2, CDCA2, BUB1, CDC2, and TYMS, and cancer-testis antigens, including MAGEA6, MAGEA3, GAGE1, and GAGE4, were the most up-regulated genes.

Samples from patients in group I exhibited the lowest frequency for cytogenetic abnormality; only 14% (4/28) of specimens demonstrated an abnormal karyotype. Up-regulation of genes in this group, including Ig genes, neutrophil cell marker DEFA, and macrophage marker CD163, indicated that the samples had a strong immune response and were probably contaminated by some normal plasma cells and other types of cells.

Consistent with other reports, patients with IgH translocations were significantly more likely to have hypodiploid myeloma than those without IgH translocations as detected by cytogenetics. Patients with hypodiploid myeloma were detected in most translocation groups (57%; p=0.002), including group III with a CCND1 spike, group V with a MAF/MAFB spike, and group VII with a MMSET/FGFR3 spike, whereas patients with hyperdiploid myeloma were less likely to have IgH translocations and their disease fell mostly into group II (40%). The up-regulated genes in group II distinguished the specimens contained in it: guanine nucleotide binding protein (GNG11), wingless-type MMTV integration site family member 4 (Wnt4), oncogene c-Kit, and estrogen receptor 2 (ESR2). Interestingly, the Wnt signaling antagonists DKK1 and FRZB were also significantly up-regulated in this cluster.

The top uniquely and spike-like expressed gene in group VI was cystatin M (CST6), which occurred in 10% (17/177) of myeloma specimens. Most specimens in this group had a normal karyotype, which predicts a favorable outcome. Up-regulated genes included tumor transformation-related gene SCAPIN1, interleukin-6 receptor gene IL6R, and pre-B-cell colony-enhancing factor gene PBEF.

Validation and Prediction Studies

Genes discriminating the seven subgroups were selected by SAM and chi-square analysis with a 5,000-permutation adjustment. The number of discriminant probe sets per myeloma subtype, determined at a statistical significance level that had a false discovery rate of less than 1%, were as follows: group I, 404 probe sets; group II, 2,368 probe sets; group III, 1,879 probe sets; group IV, 749 probe sets; group V, 398 probe sets; group VI, 238 probe sets; and group VII, 525 probe sets. The marked differences in the number of discriminating genes for the various myeloma subtypes suggest that significant differences exist in the global gene expression profiles of multiple myeloma that are likely to depend on specific defining genetic lesions.

To evaluate whether those uniquely expressed genes in the subgroups were sufficiently robust for subclasses to be correctly assigned, we then used PAM (prediction analysis for microarrays) based on nearest shrunken centroids to devise a cross-validated gene expression predictor with the top 50 ranked probe sets from each of the seven subgroups. With 350 features (probe sets), PAM predicted correct diagnosis in 91% of training specimens. FIG. 10C illustrates seven distinct groups of either overexpressed or underexpressed genes in a two-dimensional clustering analysis.

PAM was used to predict the classes of 174 independently tested cases. Each test-set sample was individually assigned to a subgroup by determining whether its expression signature across the 350 predictive genes was more highly correlated with the average signature in the seven subtype training sets. With this procedure, the same seven subgroups that were highly correlated with the training group were defined in the testing set, which yielded seven distinct hot spots (FIG. 10D). Notably, when we applied the same procedure to subgroups of samples with recurrent translocation and ploidy change, it also identified classes associated with recurrent translocations and hyperdiploidy or hypodiploidy. A strong correspondence was observed between samples represented in subtype groups II, V, and VII and those demonstrating CCND1, MAF/MAFB, and MMSET spikes, respectively (FIG. 10D). In addition, group III contained myeloma subtypes that were mostly hyperdiploid and rarely hypodiploid (p=0.012; Table 11), whereas groups associated with recurrent translocations contained more myeloma subtypes with hypodiploidy (Table 11).

Prognosis and Clinical Parameters in Both Training and Testing Groups

To investigate whether there are significant differences in outcome in patient cohorts from the seven groups, Kaplan-Meier analysis was performed for both event-free survival and overall survival. The probability of event-free survival and overall survival were significantly or marginally significantly different among the seven subtypes in both the training (p=0.053) and the testing (p=0.047) sets (data not shown). Because the event percentage was small (12%), the seven subgroups were further combined into two risk groups based on visual appearance of the survival curves. Groups I, II, III, and VI were combined as group A, and groups IV, V, and VII as group B. Notably, it was clear that group A was highly correlated with a good outcome and group B with a poor outcome with respect to event-free survival and overall survival in both training (FIGS. 11A, 11D) and testing (FIGS. 11B, 11E) sets. Group A is thus a low risk group, and group B is a high risk group.

To further assess the validity of the clusters with respect to clinical features, correlations of various clinical parameters were analyzed across the seven subgroups in both training and testing sets (Tables 10 and 11). Of 15 clinical variables tested, increases in IgA isotype (p<0.001) and serum β₂-microglobulin (p<0.05) were significantly different in groups IV, V, and VII. These clinical features, together with the gene expression profile results, were consistent with a poor outcome for patients in groups IV, V, and VII and with a favorable clinical course for patients in groups I, II, III, and VI.

Importantly, the incidence of lytic bone lesion disease was significantly different among the seven subgroups (Tables 10 and 11). In group VI, the frequency of a lytic bone lesion in training and testing sets was, respectively, 30% (average 70%) and 50% (average 80%) for patients with at least one lesion on magnetic resonance imaging (MRI) and only 23% (average 60%) and 25% (average, 65%) in patients with at least three lesions on MRI. Expression levels of FRZB and DKK1, the Wnt-signaling antagonist, and the association of lytic bone lesions with myeloma were significantly lower in group VI than in other groups.

Subgroup-Representative Genes, a 15-Gene Model

An exhaustive search was performed for smaller numbers of genes that could be used to distinguish the classes on the basis of expression signature of individual samples. The number of genes required for an optimal assignment of class varied among the classes. Because the spike genes associated with 14q translocation were easy to identify, a signal gene such as FGFR3 or MMSET, MAF or MAFB, and CCND1, was sufficient to give an almost 100% accuracy for translocation-related groups. Thus, 40% of patients were assigned to one of the three translocation subgroups. Next, using the signal intensity of the top 50 significant genes from each of the other four subgroups, we applied multivariate stepwise discriminant analysis (MSDA) and identified all the possible representative genes that could correctly distinguish tissue samples. A set of 120 samples from nontranslocation groups after defining the translocation subgroups were used. Among 200 genes, MSDA identified 10 genes that had an accuracy of 84% in predicting the sample types in the four nontranslocation subgroups and an accuracy of more than 92% in predicting the sample types in all seven training subgroups.

Next, the three translocation-related groups were defined by searching for spikes of CCND1, MAF/MAFB, and MMSET in an independent set of 174 samples (validation set). Sixty-three cases (36%) were assigned to one of the three translocation subgroups. The remaining 111 patients, corresponding to 31 samples in group I, 49 samples in group II, 16 samples in group IV, and 15 samples in group VI, were assigned to one of the four nontranslocation groups with the 10 genes identified by MSDA in the training set. MSDA was again performed on these 111 testing samples and achieved a 90% accuracy from these four groups. A final prediction accuracy of more than 95% was achieved for the entire 174-sample validation set. FIG. 12 illustrates the 15-gene model representing the seven subgroups in both training and testing sets.

In addition to the recurrent translocation-related genes, we discovered several genes implicated in diverse biological processes and pathways. Genes that distinguished group I from the other groups included secreted Ig light chain gene and fibrinogen-like 2 (FGL2). Genes that discriminated group II from the remaining groups included tumor necrosis factor-related apoptosis-inducing ligand (TRAIL), signal transduction G-protein-coupled receptor protein signaling pathway (GNG11), and insulin gene enhancer protein (ISL2). Genes distinguishing group IV from other groups included those implicated in the onset of DNA replication and cell division (MCM2) and an unknown gene. Genes for two RAS-related signaling molecules, RAB7L1 and HRASLS, and for mitogen-activated protein kinase kinase kinase kinase 3 (MAP4K3) were shown to distinguish group VI from the other groups.

To further test the validity of this model, we analyzed clinical parameters and event-free and overall survival (n=176). Seven new subgroups were generated with the 15-gene-model, and Kaplan-Meier analysis was performed to determine event-free and overall survival and clinical parameters. As expected, patients with samples in groups IV, V, and VII (group B) had a poorer outcome than those with samples in groups I, II, III, and VI (group A) (FIGS. 11C, 11F; Table 12). Table 13 shows a comparison of patient classification using 350 genes and the 15-gene model.

Summary

Gene expression profiles (GEP) of ˜33,000 genes were determined in CD-138 enriched plasma cells from 351 newly diagnosed multiple myeloma cases. A total of 2,800 genes exhibited a high degree of expression variation (S.D.>0.6) across a training set of 177 cases. Unsupervised hierarchical cluster analysis identified seven distinct subgroups with strong correlations to known translocations and cytogenetic abnormalities. The sample dendrogram created two major branches. Cases of multiple myeloma that tended to have normal karyotypes (Group I, n=38) and hyperdiploid karyotypes (Group II, n=36) were located on one branch. These two are cytogenetically-defined low risk entities. The other main branch consisted of 5 minor branches and each branch had a unique constellation of genes and cytogenetic features. CCND1 spikes, a feature indicative of the presence of a t(11;14)(q13q34) translocation, defined Group III (n=30). Group IV (n=16) was defined by a proliferation-signature either in the context of a hyper or non-hyperdiploid karyotype. MAF and MAFB spikes, indicative of the presence of either the t(14;16)(q34;p16) or t(14;20)(q34;______) translocations, clustered together and defined Group V (n=10). Group VI (n=21), which was not defined by any of the above parameters, was characterized by elevated expression of CST6. Cases with MMSET spikes resulting from a t(4;14)(p16;q32) translocation defined Group VII (n=26).

These groups also differed with respect to multiple clinical characteristics. Multiple myeloma cases with an IgA isotype were predominant in Groups V, VI, and VII (p=0.009). b2M levels were significantly elevated in Group IV (mean 7.66 mg/L) and Group V (mean 9.09 mg/L) (p=0.003). Creatinine (≧2.0 mg/dL) (p=0.005) and LDH (UI/L) (p=0.003) were significantly elevated in Group IV. Cytogenetic abnormalities predominated in Groups IV and VII (p=0.0002). When abnormal karyotypes were present, they tended to be hyperdiploid in Groups II and IV (p=0.001) and hypodiploid in Groups IV and VII (p=0.002). Group VI had a low incidence of MRI-defined focal lesions<3 MRI lesions (p=0.001). Finally, as expected, FISH detectable 14q32 translocations predominated in Groups III, V, and VII (p<0.0001).

SAM (significance analysis of microarrays) and Chi-square analysis were used to identify 50 genes whose expression uniquely defined each of these seven subgroups. Combining the 350 derived genes (7×50), a PAM analysis (prediction analysis for microarrays) was performed on the 177 training set to determine the degree of correlation with the original unsupervised cluster analysis. This analysis revealed 91% accuracy between the two tests. The 350 gene PAM model was then applied to a test group of 174 cases. The resulting cluster designations were highly correlated with a similar distribution of cytogenetic and clinical parameters seen in training and test sets. Kaplan-Meier test of event-free survival (EFS) and overall survival (OS) on the seven different groups resulted in a marginal separation. Based on the trends in these data and previously published data, the groups were separated into low-risk (Groups I, II, III, VI) and high-risk (Groups IV, V, VII) and Kaplan-Meier tests were repeated. The data showed significant differences in both the training set (EFS, p<0.0002; OS, p=0.0033) and the test set (EFS, p=0.021; OS, p=0.0015).

Multivariate Discriminant Analysis was then used to derive a model based on the expression levels of 15 genes that could accurately discriminate the seven groups in training and test sets. When all 351 cases were classified by the 15 gene model and characterized as low and high risk as defined above, Kapalan Meier analysis revealed significant differences in both event-free survival and overall survival (p<0.05). Taken together these data suggests that multiple myeloma is broad descriptor of seven discrete molecular entities each with unique mechanisms of transformation that give rise to group-specific deregulated gene expression and differing outcomes. A small scale quantitative RT-PCR-based assay based on the 15-gene model could allow rapid application of this new 15 gene classification schema as a novel risk stratification model. This new 15-gene model can be used not only in current HDT tandem transplants but also in new therapies that would include the incorporation of new agents like bortezimib and REVLIMID therapies as well as to develop subgroup-specific treatment strategies.

TABLE 10 Characteristic of 177 Multiple Myeloma Patients in the Training Set in Relation to the Seven Subgroups Identified by Hierarchical Clustering Group I II III IV V VI VII P-value Age >=65 12/38 (32%) 6/36 (17%) 5/30 (17%) 2/16 (13 3/10 (30%) 5/21 (24 4/26 (15%) 0.563* IgA Isotype 6/32 (19%) 6/33 (18%) 4/24 (17%) 2/15 (13%) 5/10 (50%) 7/20 (35%) 14/26 (54%) 0.009* Albumin <3.5 4/38 (11%) 5/36 (14%) 5/30 (17%) 4/16 (25%) 0/10 (0%) 3/21 (14%) 4/26 (15%) 0.741* g/dL B2M (mg/L)  2.73  3.49  5.68  7.66  9.09  5.59  4.26 0.003^(#) CRP >=4 mg/L 19/38 (50%) 19/34 (56%) 17/30 (57%) 10/16 (63%) 4/10 (40%) 10/21 (48%) 13/25 (52%) 0.927 Cytogenetics 7/38 (18%) 15/36 (41%) 7/30 (23%) 12/16 (75%) 2/10 (20%) 4/21 (19%) 14/26 (53%) 0.0002 abnormality Hyperdiploidy 4/38 (10%) 13/36 (36%) 0/30 (0%) 6/16 (37%) 1/10 (10%) 2/21 (9%) 5/26 (19%) 0.0011 Hypodiploidy 2/38 (5%) 3/36 (8%) 5/30 (16%) 6/16 (37%) 1/10 (10%) 2/21 (9%) 10/26 (38%) 0.0022 MRI >1 28/36 (77%) 26/36 (72%) 28/30 (93%) 14/15 (93%) 7/10 (70%) 10/20 (50%) 18/26 (69%) 0.0144 MRI >3 24/36 (66%) 19/36 (52%) 22/30 (73%) 14/15 (93%) 4/10 (40%) 5/20 (25%) 16/26 (61%) 0.0010 Chr14 >20 8/16 (50%) 7/21 (33%) 15/15 (100%) 8/12 (66%) 3/3 (100%) 4/10 (40%) 13/13 (100%) 3.82 × 10⁻⁵ LDH(UI/L) 183.11 172.69 179.27 246.25 187.10 160.52 155.04 0.003^(#) Creat- 0/38 (0%) 1/36 (3%) 5/30 (17%) 4/16 (25%) 2/10 (20%) 4/21 (19%) 2/26 (8%) 0.005* inine >=2.0 mg/dL HGB <10 g/dL 8/38 (21%) 6/36 (17%) 6/30 (20%) 5/16 (31%) 2/10 (20%) 8/21 (38%) 7/26 (27%) 0.618* *Fisher's exact test was used. ^(#)ANOVA test was used. Bold = top significant group.

TABLE 11 Characteristic of 174 Multiple Myeloma Patients in the Testing Set in Relation to the Seven Subgroups Identified by PAM Prediction Group I II III IV V VI VII P-value Age >=65 9/31 (29%) 6/49 (12%) 7/29 (24%) 3/16 (19%) 2/10 (20%) 1/15 (7%) 4/24 (17%) 0.468* IgA Isotype 4/29 (14%) 4/45 (9%) 5/25 (20%) 3/14 (21%) 5/9 (56%) 8/12 (67%) 10/22 (45%) <.001* Albumin <3.5 2/31 (6%) 6/49 (12%) 6/29 (21%) 7/16 (44%) 1/10 (10%) 1/15 (7%) 4/24 (17%) 0.058* g/dL B2M(mg/L)  3.3  3.63  4.73  7.81  8.04  3.57  4.52 0.029^(#) CRP >=4 mg/L 18/31 (58%) 26/49 (53%) 17/29 (59%) 10/16 (63%) 5/9 (56%) 8/15 (53%) 9/24 (38%) 0.743* Cytogenetics 5/31 (16%) 21/49 (42%) 7/29 (24%) 9/16 (56%) 5/10 (50%) 2/15 (13%) 14/24 (58%) 0.0025 abnormality Hyperdiploidy 4/31 (12%) 18/49 (36%) 1/29 (3%) 4/16 (25%) 1/10 (10%) 2/15 (13%) 4/24 (16%) 0.012 Hypodiploidy 1/31 (3%) 3/49 (6%) 2/29 (6%) 4/16 (25%) 5/10 (50%) 0/15 (0%) 10/24 (41%) 3.82 × 10⁻⁶ MRI >1 29/30 (96%) 36/46 (78%) 21/27 (77%) 15/16 (93%) 6/9 (66%) 4/13 (30%) 15/24 (62%) 0.0001 MRI >3 21/30 (70%) 26/46 (56%) 18/27 (66%) 11/16 (68%) 3/9 (33%) 3/13 (23%) 12/24 (50%) 0.049 Chr14 >20 7/17 (41%) 8/29 (27%) 9/11 (81%) 4/9 (44%) 3/3 (100%) 3/7 (42%) 15/15 (100%) 6.94 × 10⁻⁵ LDH >=190 UI/L 184.45 159.22 172.97 193.94 207.67 171.90 195.78 0.314^(#) Creat- 3/31 (10%) 2/49 (4%) 6/29 (21%) 3/16 (19%) 1/10 (10%) 0/15 (0%) 4/24 (17%) 0.129* inine >=2.0 mg/dL HGB <10 g/dL 6/31 (19%) 10/49 (20%) 11/29 (38%) 9/16 (56%) 3/10 (30%) 6/15 (40%) 6/24 (25%) 0.091* *Fisher's exact test was used. ^(#)ANOVA test was used. Bold = top significant group.

TABLE 12 Characteristic of 176 Multiple Myeloma Patients in the Predicting Set in Relation to the Seven Subgroups Identified by the 15-Gene Model Group I II III IV V VI VII P-value Age >=65 9/36 (25%) 5/52 (10%) 3/25 (12%) 2/12 (17%) 0/4 (0%) 1/18 (6%) 5/29 (17%) 0.438* IgA Isotype 5/35 (14%) 6/51 (12%) 3/24 (13%) 2/12 (17%) 1/4 (25%) 6/17 (35%) 11/29 (38%) 0.055* Albumin <3.5 3/36 (8%) 5/52 (10%) 7/25 (28%) 4/12 (33%) 0/4 (0%) 3/18 (17%) 6/29 (21%) 0.133* g/dL B2M (mg/L)  3.17  3.50  4.27  8.73  4.33  3.74  4.56 0.007^(#) CRP >=4 mg/L 19/36 (53%) 26/50 (52%) 14/25 (56%) 6/11 (55%) 1/4 (25%) 10/18 (56%) 14/29 (48%) 0.965* Cytogenetics 9/27 (33%) 22/46 (48%) 9/23 (39%) 6/9 (56%) 2/3 (67%) 5/16 (31%) 14/27 (52%) 0.598 abnormality Hyperdiploidy 7/27 (26%) 20/46 (43%) 0/23 (0%) 2/9 (22%) 0/3 (0%) 3/16 (19%) 4/27 (15%) 0.004 Hypodiploidy 2/27 (7%) 2/46 (4%) 9/23 (39%) 3/9 (33%) 2/3 (67%) 2/16 (13%) 10/27 (37%) 0.0002 MRI >1 31/34 (91%) 44/52 (85%) 23/25 (92%) 11/12 (92%) 3/4 (75%) 6/17 (35%) 18/29 (62%) 1.70 × 10⁻⁵ MRI >3 25/34 (74%) 28/52 (54%) 18/25 (72%) 11/12 (92%) 2/4 (50%) 4/17 (24%) 15/29 (52%) 0.002 Chr14 >20 16/27 (59%) 15/45 (33%) 17/20 (85%) 6/10 (60%) 3/3 (100%) 5/15 (33%) 23/23 (100%) 4.30 × 10⁻⁷ LDH(UI/L) 180.72 169.29 156.12 235.33 164.75 173.11 147.89 0.029^(#) Creat- 2/36 (6%) 4/52 (8%) 1/25 (4%) 3/12 (25%) 0/4 (0%) 1/18 (6%) 4/29 (14%) 0.403* inine >=2.0 mg/dL HGB <10 g/dL 6/36 (17%) 9/52 (17%) 9/25 (36%) 6/12 (50%) 2/4 (50%) 7/18 (39%) 7/29 (24%) 0.064* *Fisher's exact test was used. ^(#)ANOVA test was used. Bold = top significant group.

TABLE 13 Comparison of Patient Classification Using 350 Genes and The 15-Gene Model Subgroups 15-Gene Model PAM with 350 Genes 1 2 3 4 5 6 7 Accuracy (%) G1 (n = 69) 59 85.51 G2 (n = 85) 78 91.76 G3 (n = 59) 54 91.53 G4 (n = 31) 27 87.10 G5 (n = 20) 18 90.00 G6 (n = 36) 34 94.44 G7 (n = 50) 48 96.00 Total 90.60

EXAMPLE 13 Endothelin B Receptor as a Potential Therapeutic Target of Multiple Myeloma

As disclosed above, the present invention has identified a number of genes that have significantly different expression levels in plasma cells derived from multiple myeloma compared to those of normal control. Genes that are significantly up-regulated or down-regulated in multiple myeloma are potential therapeutic targets of multiple myeloma. Examples of these genes are listed in Tables 4, 5 and 8. Among these differentially expressed genes is endothelin B receptor (ENDBR). This gene was not expressed in normal plasma cells, but does show highly elevated expression in a subset of myeloma. In fact, this gene now appears to be highly expressed in between 30-40% of myeloma patients. FIGS. 14A-14B shows a comparison of ENDBR expression in normal plasma cells and in approximately 200 myeloma patients starting with P1 through P226. ENDBR was either off or highly expressed in multiple myeloma patients (FIG. 14A). Levels of ENDBR expression levels were approximately the same in newly diagnosed and previously treated patients, suggesting that the activation is not a progression event (FIG. 14B).

Several important features of ENDBR should be noted. The ENDBR gene is located on chromosome 13. This is of potential significance given that abnormalities in chromosome 13 such as translocation or deletions represent one of the most powerful negative risk factors in multiple myeloma. Thus, it is possible that the hyperactivation of ENDBR expression could be an indicator of poor prognosis for multiple myeloma. There are also extensive reports linking endothelin signaling to cell growth, and endothelins have been shown to activate several key molecules with documented pathological roles in plasma cell tumorigenesis. Of note are the c-MYC oncogene, a gene that is activated in 100% of mouse plasmacytomas and hyperactivated in many primary human myeloma cells, and IL-6 which is a major growth and survival factor for myeloma cells. The endothelins also appear to exert their signaling through the phospholipase C pathway, a major signaling pathway in B-cells. Moreover, a recent paper reported that blocking endothelin signaling resulted in inhibition of the proliferation of Kaposi's sarcoma cells.

When the tumor cells of multiple myeloma patients were taken out of the microenvironment of bone marrow, the tumor cells did not appear to express endothelins genes in a large proportion of the population. They lack expression of the endothelin 1, 2 and 3 in most cases. However, when the myeloma cells were taken out of the bone marrow and cultured for 48-72 hours on proprietary feeder layer that mimics the bone marrow microenvironment, endothelin 1 gene expression was massively up-regulated in both the myeloma cells P323 and P322 as well as the feeder layer (FIGS. 15A-15B). Hence, a major variable within multiple myeloma may be the availability of endothelins. Enhanced production of endothelins coupled with up-regulated expression of ENDBR in local areas may contribute to the neoplastic phenotype of multiple myeloma, and blocking endothelins and endothelin receptor interaction may disrupt the development of the malignant phenotype.

EXAMPLE 14 Comparative Gene Expression Profiling of Human Plasma Cell Differentiation

Examples 14-16 describe global gene expression profiling that reveals distinct changes in transcription associated with human plasma cell differentiation. Data presented below demonstrate for the first time that highly purified plasma cells could be isolated from two unique hematopoietic organs, tonsil and bone marrow. This purification of millions of cells eliminated background “noise” from non-specific cell types (FIGS. 16A-16X), thereby allowing accurate genetic profile and characterization of these samples using highly sensitive gene expression profiling technology. The results disclosed herein characterized molecular transcription changes associated with different cell stages and especially distinguishing differences in plasma cell, a cell previously thought to represent an end-stage differentiation product based on morphological criterion.

The CD19⁺ tonsil B cells and CD138⁺ plasma cells isolated from tonsil and bone marrow used in the study represent homogeneous populations with unique phenotypic characteristics. Thus, results presented are based on well-characterized cells as shown by flow cytometry, morphology, and expression of cIg. These results are important because although great efforts have been made to understand B cell development, little is known about plasma cells, most likely due to their scarcity with most previous studies focusing only on flow cytometric characterizations.

Another unique finding from the results is that B cells and plasma cells segregated into two branches using a hierarchical gene expression cluster analysis. Further, within the plasma cell branch, tonsil plasma cells could be distinguished from bone marrow plasma cells, indicating that the cells represent unique stages of development as suspected from their derivation from unique hematopoietic organs. Genes identified herein. e.g., cell surface markers and transcription factors, matched those previously identified as distinguishing late-stage B cell development. In addition to the novel genes found, previously identified genes followed expected patterns of up- and down-regulation and matched those genes already shown to be linked to plasma cell differentiation or essential transcription factors for plasma cell differentiation.

Although cells at distinct stages of B cell development express CD19, it is likely that the majority of the tonsil B cells studied here represent germinal center centroblasts. It is known that centrocytes and centroblasts of germinal centers can be differentiated based on the expression of CD44 (centrocytes, CD44⁺; centroblasts, CD44⁻). Expression of the CD44 gene was undetectable in the tonsil B cell samples used in this study. In addition, the high level of expression of genes linked to proliferation, e.g. MKI67, PCNA, and CCNB1 (data not shown) suggests blasts make up the largest population of cells among the tonsil B cells. Finally, MYBL, whose expression is a marker of CD38⁺ CD39⁻ centroblasts, was found to be highly expressed in the tonsil B cells, down-regulated in tonsil plasma cells (p=0.00068), and extinguished in bone marrow plasma cells. Because centroblasts have already undergone switch recombination, the tonsil B cells studied here represent an optimal late stage B cell population to use in a comparative study of gene expression changes associated with early plasma cell differentiation.

A representative analysis of normal cell types used in this study is presented in FIG. 16A-16X. FACs analysis of the tonsil preparations before sorting indicated that CD20^(hi)/CD38^(lo) cells represented 70% and CD38⁺/CD20⁻ cells represented 30% of the population (FIGS. 16A-16B). After anti-CD19 immunomagnetic bead selection, the CD20^(hi)/CD38^(lo/−) cells were enriched to 98% and the CD38⁺/CD20⁻, CD138⁻/CD20⁺, and CD138⁻/CD38⁺ fractions represented 1% of the population (FIGS. 16B, 16C, 16E, 16F). Cell morphology of the purified fraction also showed that the majority of cells had typical B cell morphology (FIG. 16G). Immunofluorescence microscopy with anti-kappa and anti-lambda antibodies indicated a slight contamination with cIg⁺ CD19⁺ cells (FIG. 16H).

Before tonsil plasma cell isolation, FACs analysis of the tonsil mononuclear fractions indicated that CD38^(hi)/CD45^(lo) (FIG. 16I) and CD138^(hi)/CD45⁻ cells (FIG. 16J) represented 2.4% of the population. After anti-CD138 immunomagnetic bead sorting, cells with a plasma cell phenotype that was either CD38^(hi)/CD45^(lo) (95%), CD138^(hi)/CD45^(lo) (94%), CD38^(h)/CD20^(lo) (91%), or CD138^(hi)/CD38^(hi) (92%) were greatly enriched (FIGS. 16K-16M). The tonsil CD138-selected cells were also found to have a typical plasma cell morphology with increased cytoplasmic to nuclear ratio of prominent perinuclear Hoff or endoplasmic reticulum (FIGS. 16O) and >95% of the cells were cIg positive (FIG. 16P).

FACs analysis prior to anti-CD138 immunomagnetic bead sorting of bone marrow mononuclear cell samples showed similar but distinct profiles in comparison with the tonsil preparations. CD38^(hi)/CD45^(int) and CD138^(hi)/CD45^(int) fractions showed more cells with lower expression of CD45 and a higher percentage of CD138⁺ cells in the bone marrow plasma cells (FIGS. 16Q-16R). FACS analysis after purification showed that the CD38^(hi)/CD45⁻ and CD38^(hi)/CD20^(lo) cells were enriched to 99% and 91%, respectively (FIGS. 16S, 16U). Differences between tonsil plasma cells and bone marrow plasma cells after sorting were also evident, in that whereas the tonsil plasma cells had clear evidence of CD38⁺/CD45⁺ and CD38⁺/CD20⁺ cells, these fractions were greatly reduced in the bone marrow CD138-selected cells. Bone marrow plasma cells also expressed higher levels of CD38 than the tonsil plasma cells (FIGS. 16S, 16K). The CD138^(hi)/CD45⁻ and CD138^(hi)/CD38^(hi) populations represented 96% and 95% of the bone marrow plasma cell population (FIGS. 16T, 16V), again with a reduced amount of CD45⁺ cells and higher percentage of CD38⁺ cells as compared with tonsil plasma cells. As with the tonsil plasma cells, the majority of the bone marrow cells had plasma cell morphology (FIG. 16W) and were cIg positive (FIG. 16X). Thus, immunomagnetic bead selection resulted in the purification of a relatively homogenous tonsil B cell population and distinct plasma cell populations from two different organs, likely representing cells at different stages of maturation.

Having demonstrated the phenotypic characteristics of the cells, the global mRNA expression was then analyzed in 7 tonsil B cell, 11 tonsil plasma cell, and 31 bone marrow plasma cell samples using the Affymetrix high-density oligonucleotide microarray interrogating approximately 6800 named and annotated genes. The mean value of the AD expression level of genes for the CD markers used in the cell analysis, as well as other CD markers, chemokine receptors, apoptosis regulator, and a panel of transcription factors were analyzed across the normal samples (Table 14). CD45 was found to be highly expressed on tonsil B cells, with lower expression on tonsil plasma cells, and absent on bone marrow plasma cells. The genes for CD20, CD79B, CD52, and CD19 showed CD45-like expression patterns with progressive down-regulation from tonsil B cells to tonsil plasma cells. Although CD21 showed no significant change from tonsil B cells to tonsil plasma cells, the gene was down-regulated in bone marrow plasma cells. CD22, CD83, and CD72 showed progressive down-regulation.

Consistent with the FACS analysis, Syndecan-1 (CD138) and CD38, key plasma cell differentiation antigens, were absent or weakly expressed on tonsil B cells, with intermediate levels on tonsil plasma cells, and highest expression on bone marrow plasma cells. The intermediate level of CD138 expression is likely a direct reflection of the heterogeneous mixture of CD138⁺ cells in the tonsil plasma cell fraction (see above) with some cells being highly CD138⁺ and others weakly positive but still able to be sorted based on surface expression of CD138. CD38 expression showed the progressive increase seen with CD138 in the normal cells.

It was also observed that the CD63 gene was significantly up-regulated in bone marrow plasma cells. This is the first indication that this marker may be differentially regulated during plasma cell differentiation. The gene for CD27 showed significant up-regulation from the B cell to tonsil plasma cell transition, whereas bone marrow plasma cells and tonsil plasma cells showed similar levels.

Transcription factors differentially expressed in plasma cell development showed the expected changes. IRF4 and XBP1 were significantly up-regulated in tonsil and bone marrow plasma cells and CTIIA, BCL6, and STAT6 were down-regulated in the plasma cell samples. BSAP (PAX5) did not show the expected changes, but it is believed that this was due to an ineffective probe set for the gene because the BSAP target gene, BLK, did show the expected down-regulation in the tonsil and bone marrow plasma cells. Interestingly, whereas MYC showed significant down-regulation in the tonsil B cell to tonsil plasma cell transition, the gene was reactivated in bone marrow plasma cells to levels higher than seen in the tonsil B cells. Whereas the chemokine receptors CXCR4 and CXCR5 showed down-regulation in the tonsil B cell to tonsil plasma cell transition, CXCR4 showed a MYC-like profile in that the gene was reactivated in bone marrow plasma cells. The BCL2 homologue BCL2A1 also showed the expected changes. Thus, gene expression patterns of cell surface markers are consistent with phenotypic patterns and genes known to be strongly associated with plasma cell differentiation showed anticipated patterns. These data support the notion that the tonsil B cells, tonsil plasma cells, and bone marrow plasma cells represent distinct stages of B-cell differentiation and that gene expression profiling of these cells can be used to gain a better understanding of the molecular mechanisms of differentiation.

TABLE 14 Gene Expression of CD Marker and Proteins Known to be Differentially Expressed during Plasma Cell Differentiation Accession Symbol TBC TPC BPC Y00062 CD45 11495 ± 2198 4979 ± 2522 1385 ± 706  M27394 CD20 23860 ± 5494 3799 ± 2977 289 ± 358 M89957 CD79B 14758 ± 3348 4696 ± 2440 1243 ± 1357 X62466 CD52 14576 ± 2395 4348 ± 2074 2831 ± 1002 M84371 CD19 12339 ± 1708 6174 ± 1345 2852 ± 852  M26004 CD21  8909 ± 1640 5434 ± 4053 458 ± 140 X59350 CD22 10349 ± 1422 5356 ± 1610 1929 ± 612  Z11697 CD83  9201 ± 1900 2380 ± 1087 392 ± 403 M54992 CD72  6177 ± 1620 865 ± 554 454 ± 548 Z48199 CD138  719 ± 519 9935 ± 3545 24643 ± 6206  D84276 CD38 3122 ± 967 9833 ± 3419 14836 ± 3462  X62654 CD63 2310 ± 431 6815 ± 1582 16878 ± 3305  M63928 CD27  6235 ± 1736 15937 ± 6691  16714 ± 4442  M31627 XBP1 12978 ± 1676 54912 ± 13649 49558 ± 10798 U52682 IRF4 1863 ± 630 8422 ± 3061 11348 ± 3118  U00115 BCL6  7979 ± 1610 3303 ± 2070 618 ± 335 X74301 CIITA 1553 ± 263 236 ± 217 113 ± 82  U16031 STAT6 1314 ± 512 386 ± 335 191 ± 187 S76617 BLK  3654 ± 1551 388 ± 592 95 ± 86 X68149 CXCR5  3381 ± 1173 183 ± 299  92 ± 183 U29680 BCL2A1  3290 ± 1073 1121 ± 817  483 ± 209 L00058 MYC 1528 ± 474 348 ± 239 2103 ± 903  L06797 CXCR4 11911 ± 2093 6673 ± 3508 18033 ± 5331  Accession = GENBANK accession number. Symbol = HUGO approved gene symbol. The numbers in the columns under the tonsil B cell (TBC), tonsil plasma cell (TPC), and bone marrow plasma cell (BPC) samples represent the mean average difference (AD) value ± the standard deviation (STD) for the given gene. Differences in expression across comparisons were significant (p < 0.01) unless indicated in bold.

EXAMPLE 15 Identification of Differentially Expressed Genes in the Tonsil B Cell to Tonsil Plasma Cell Transitions and in the Tonsil Plasma Cell to Bone Marrow Plasma Cell Transitions

A more detailed and comprehensive evaluation was performed to determine gene expression changes that accompany the transition of tonsil B cells to tonsil plasma cells and the changes that occur as the immature tonsil plasma cells exit the lymph node germinal center and migrate to the bone marrow. To reveal global expression distinctions among the samples, hierarchical cluster analysis was performed with 4866 genes in 7 tonsil B cell, 7 tonsil plasma cell, and 7 bone marrow plasma cell cases (FIG. 17). As expected, this analysis revealed a major division between the tonsil B cell samples and plasma cell samples with the exception of one tonsil plasma cell sample being clustered with tonsil B cell. The normal plasma cells were further subdivided into two distinct groups of tonsil plasma cells and bone marrow plasma cells. Thus, global gene expression patterns confirmed the segregation of tonsil plasma cells and bone marrow plasma cells and also allowed the distinction of tonsil B cells from both plasma cell types.

c2 and Wilcoxon rank sum analysis were used to identify 359 and 500 genes whose mRNA expression levels were significantly altered (p<0.00005) in the tonsil B cell to tonsil plasma cell and tonsil plasma cell to bone marrow plasma cell comparison, respectively. Genes that were significantly differentially expressed in the tonsil B cell to tonsil plasma cell transition were referred as “early differentiation genes” (EDGs) and those differentially expressed in the tonsil plasma cell to bone marrow plasma cell transition were referred as “late differentiation genes” (LDGs).

Early Differentiation Genes

Of the top 50 EDGs (Table 15), most of the genes (43) were down-regulated with only 7 genes being up-regulated in this transition. Gene expression was described as being at 1 of 5 possible levels. An AAC, indicating an undetectable or absent gene transcript, was defined as “−”. For all the samples in a group, expression levels were defined as “+” if the gene transcript was present and the AD was <1000, “++” for 1000≦AD<5000, “+++” for 5000≦AD<10,000, and “++++” for AD≧10,000. The largest group of EDGs encoded transcription factors. Of 16 transcription factors, only 3, XBP-1, IRF4 and BMI1, were up-regulated EDGs. Among the down-regulated transcription factors, MYC and CIITA were found. The largest family included four ets domain-containing proteins: ETS1, SPIB, SPI1, and ELF1. Other transcription factors included the repressors EED and ID3, as well as the activators RUNX3, ICSBP1, REL, ERGS, and FOXM1. It is of potential significance that as IRF4 is up-regulated in both the tonsil B cell to tonsil plasma cell and tonsil plasma cell to bone marrow plasma cell transitions, the IRF family member interferon consensus sequence binding protein, ICSBP1, which is a lymphoid-specific negative regulator, was the only gene that was expressed at a +++ level in tonsil B cells and was shut down in both tonsil plasma cells and bone marrow plasma cells. These results suggest that the removal of ICSBP1 from IRF binding sites may be an important mechanism in regulating IRF4 function.

The second most abundant class of EDGs code for proteins involved in signaling. CASP10 which is involved in the activation cascade of caspases responsible for apoptosis execution represented the only signaling protein up-regulated in tonsil plasma cells. Three small G proteins, the Rho family members ARHG and ARHH, and the proto-oncogene HRAS were down-regulated EDGs. Two members of the tumor necrosis factor family TNF and lymphotoxin beta (LTB), as well as the TNF receptor binding protein were LDGs. Given the important role of IL-4 in triggering class-switch recombination, the observation of down-regulation (tonsil B cell to tonsil plasma cell), and eventual extinguishing (tonsil plasma cell to bone marrow plasma cell) of IL4R fits well with the differentiation states of the cells under study.

Finally, the down-regulation of the B lymphoid tyrosine kinase (BLK) whose expression is restricted to B lymphoid cells and may function in a signal transduction pathway suggests that the reduction of this kinase is important in the early stages of plasma cell differentiation. Given the important role of cell adhesion in plasma cell biology, up-regulation of ITGA6 and PECAM1 could be of particular importance. In fact, these genes also showed a continual up-regulation in the tonsil plasma cell to bone marrow plasma cell transition and represented the only extracellular adhesion genes in the EDG class. Other multiple-member classes of down-regulated EDGs included those involved in cell cycle (CCNF, CCNG2, and CDC20) or DNA repair/maintenance (TERF2, LIG1, MSH2, RPA1). The down-regulation of these genes may thus be important to inducing and/or maintaining the terminal differentiated state of the plasma cells.

Late Differentiation Genes

In the top 50 LDGs, 33 were up-regulated or turned on and 17 genes were down-regulated or turned off (Table 16). Although 16 EDGs were transcription factors, only 5 LDGs belonged to this class. The BMI1 gene, which was an up-regulated EDG, was also an LDG, indicating that the gene undergoes a significant increase in expression in both the tonsil B cell to tonsil plasma cell and tonsil plasma cell to bone marrow plasma cell transitions. BMI1 was the only up-regulated transcription factor. MYBL1, MEF2B, and BCL6 were shut down in bone marrow plasma cells and the transcription elongation factor TCEA1 was down-regulated. The largest class of LDG (n=16; 11 up- and 5 down-regulated) coded for proteins involved in signaling. The LIM containing protein with both nuclear and focal adhesion localization, FHL1; and the secreted proteins, JAG1, a ligand for Notch, insulin-like growth factor IGF1; and bone morphogenic protein BMP6 were up-regulated. The dual specific phosphatase DUSP5 and the chemokine receptor CCR2 represented genes with the most dramatically altered expression and were turned on to extremely high levels in bone marrow plasma cells while being absent in tonsil plasma cells. Additional signaling genes, including the membrane caveolae, CAV1 and CAV2, plasma membrane proteins important in transportation of materials and organizing numerous signal transduction pathways, were up-regulated LDGs.

Given the dramatic difference in life spans of tonsil plasma cells (several days) and bone marrow plasma cells (several weeks to months), the up-regulation of the anti-apoptotic gene BCL2 (− in tonsil B cells and ++ in bone marrow plasma cells) and concomitant down-regulation of the apoptosis-inducing protein BIK (+++ in tonsil B cells and − in bone marrow plasma cells) may be critical in regulating normal programmed cell death. As in the EDGs, LDGs contained multiple adhesion-related genes, and, as in the EDGs, the LDG adhesion genes were all up-regulated.

The PECAM1 gene was found to be both an EDG and LDG, suggesting that a gradation of cell surface expression of this gene is critical in development. Whereas the integrin family member ITGA6 was an EDG, ITGA4 was found to be an LDG. The finding that ITGA4 or VLA-4 (very late antigen 4) was an LDG is consistent with published data showing that this integrin is most predominant on late stage plasma cells. The adhesion molecule selectin P ligand (SELPLG) which mediates high affinity, calcium-dependent binding to P-, E- and L-selectins, mediating the tethering and rolling of neutrophils and T lymphocytes on endothelial cells, may facilitate a similar mechanism in late stage plasma cells. In addition, the epithelial membrane protein 3 (EMP3), a integral membrane glycoprotein putatively involved in cell-cell interactions, was identified. LRMP (JAW1), a lymphoid-restricted, integral ER membrane protein based on strong homology to MRVI1 (IRAG) and is likely a essential nitric oxide/cGKI-dependent regulator of IP3-induced calcium release from endoplasmic reticulum stores, was found to be a down-regulated LDG. The discovery of LRMP as a down-regulated LDG is consistent with previous studies showing that, although highly expressed in lymphoid precursors, it is shut down in plasma cells.

Thus, the gene expression profiling results confirmed previous observations as well as identified novel and highly significant changes in mRNA synthesis when tonsil B cells and tonsil plasma cells and tonsil plasma cells and bone marrow plasma cells are compared.

TABLE 15 Early-Stage Differentiation Genes: Top 50 Differentially Expressed Genes in Comparison of Tonsil B Cells and Tonsil and Bone Marrow Plasma Cells Quantitative Gene Expression Accession Symbol Function TBC TPC BPC U60519 CASP10 apoptosis − + ++ X53586 ITGA6 adhesion − + ++ U04735 STCH chaperone + ++ ++ L13689 BMI1 transcription; repressor; + ++ +++ PcG L34657 PECAM1 adhesion + ++ +++ U52682 IRF4 transcription; IRF family + +++ +++ M31627 XBP1 transcription; bZip family +++ ++++ ++++ AB000410 OGG1 DNA glycosylase + − − D87432 SLC7A6 solute transporter + − − J04101 ETS1 transcription; ets family + − − L38820 CD1D immunity + − − M28827 CD1C immunity + − − M55542 GBP1 signaling; GTP binding + − − M81182 ABCD3 ABC transporter + − − M85085 CSTF2 mRNA cleavage + − − stimulating factor U74612 FOXM1 transcription; + − − fork-head family U84720 RAE1 RNA export + − − V00574 HRAS signaling; GTP binding + − − protein X02910 TNF signaling; TNFa + − − X63741 EGR3 transcription; egr family + − − X93512 TERF2 telomere repeat binding + − − protein Z36714 CCNF cell cycle; cyclin F + − − AB000409 MNK1 signaling; kinase + − + M33308 VCL cytoskeleton + − ++ D16480 HADHA mitochondrial oxidation ++ − − M63488 RPA1 DNA replication/repair ++ − − U03911 MSH2 DNA repair ++ − − U69108 TRAF5 signaling; ++ − − TNFR associated protein X12517 SNRPC mRNA splicing ++ − − X52056 SP11 transcription; ets family ++ − − X68149 BLR1 signaling; cxc receptor ++ − − X74301 CIITA transcription; adaptor ++ − − X75042 REL transcription; rel/dorsal ++ − − family L00058 MYC transcription; bHLHZip ++ − ++ M36067 LIG1 DNA ligase ++ + + M82882 ELF1 transcription; ets family ++ + + S76617 BLK signaling; kinase ++ + + U47414 CCNG2 cell cycle; cyclin G ++ + + U61167 SH3D1B unknown; ++ + + SH3 containing protein X61587 ARHG signaling; Rho G ++ + + Z35278 RUNX3 transcription; ++ + + contains runt domain M91196 ICSBP1 transcription; IRF family +++ − − M34458 LMNB1 cytoskeletal matrix +++ + − U90651 EED transcription; repression; +++ + + PcG X69111 ID3 transcription; repression; +++ + + bHLH X52425 IL4R signaling; cytokine receptor +++ ++ − Z35227 ARHH signaling; Rho H +++ ++ + U89922 LTB signaling; TNF-c ++++ + + U05340 CDC20 cell cycle; activator of APC ++++ ++ − X66079 SPIB transcription; ets family ++++ ++ − Accession = GENBANK accession number. Symbol = HUGO approved gene symbol. TBC, tonsil B cell; TPC, tonsil plasma cell; BPC, bone marrow plasma cell; AD, mean average difference; AC, absolute call. Quantitative gene expression: −, AC absent; +, AC present and AD < 1,000; ++, AD = 1,000 to 5,000; +++, AD = 5,000 to 10,000; ++++, AD > 10,000.

TABLE 16 Late-Stage Differentiation Genes: Top 50 Differentially Expressed Genes in Comparison of Tonsil and Bone Marrow Plasma Cells Quantitative Gene Expression Accession Symbol Function TPC BPC U32114 CAV2 signaling; membrane caveolae − + U60115 FHL1 signaling; LIM domain − + U73936 JAG1 signaling; Notch ligand − + X57025 IGF1 signaling; growth factor − + Z32684 XK membrane transport − + D10511 ACAT1 metabolism; ketone − ++ Y08999 ARPC1A actin polymerization − ++ M14745 BCL2 signaling; anti-apoptosis − ++ M24486 P4HA1 collagen synthesis − ++ M60315 BMP6 signaling; TGF family − ++ U25956 SELPLG adhesion − ++ X16983 ITGA4 adhesion − ++ Z18951 CAV1 signaling; membrane caveolae − ++ M60092 AMPD1 metabolism; energy − +++ U15932 DUSP5 signaling; phosphatase − ++++ U95626 CCR2 signaling; chemokine receptor − ++++ D78132 RHEB2 signaling; ras homolog + ++ L41887 SFRS7 mRNA splicing factor + ++ M23161 LOC90411^(a) unknown + ++ M37721 PAM metabolism; hormone amidation + ++ M69023 TSPAN-3^(a) unknown + ++ U02556 TCTE1L dynein homolog + ++ U41060 LIV-1^(a) unknown + ++ U44772 PPT1 lysosome enzyme + ++ U70660 ATOX1 metabolism; antioxidant + ++ X92493 PIP5K1B signaling; kinase + ++ M23254 CAPN2 cysteine protease + +++ J02763 S100A6 signaling; calcium binding ++ +++ L13689 BMI1 transcription; represser; PcG ++ +++ L34657 PECAM1 adhesion ++ +++ M23294 HEXB metabolism; hexoaminidase ++ +++ M64098 HLDBP metabolism; sterol ++ ++++ U52101 EMP3 adhesion ++ ++++ X66087 MYBL1 transcription; myb-like + − X54942 CKS2 cell cycle; kinase regulator ++ − X73568 SYK signaling; kinase ++ − L08177 EBI2 signaling; receptor ++ − M25629 KLK1 protease; serine ++ − U00115 BCL6 transcription; Zn-finger ++ − U23852 LCK signaling; kinase ++ − U60975 SORL1 endocytosis ++ − X63380 MEF2B transcription; MADs box ++ − L25878 EPXH1 metabolism; epoxide hydrolase ++ + Z35227 ARHH signaling; Rho C ++ + X89986 BIK signaling; apoptosis +++ − M13792 ADA metabolism; purine +++ + U10485 LRMP ER membrane protein +++ + M81601 TCEA1 transcription; elongation +++ ++ X70326 MACMARCK actin binding ++++ + X56494 PKM2 metabolism; energy ++++ + Accession = GENBANK accession number. Symbol = HUGO approved gene symbol. ^(a)Unapproved symbol. TPC, tonsil plasma cell; BPC, bone marrow plasma cell; AD, mean average difference; AC, absolute call. Quantitative gene expression: −, AC absent; +, AC present and AD < 1,000; ++, AD = 1,000 to 5,000; +++, AD = 5,000 to 10,000; ++++, AD > 10,000.

EXAMPLE 16 Previously Identified and Novel Genes in Plasma Cell Differentiation

In this gene expression profiling study, not only previously identified but also novel genes associated with plasma cell development were identified. Some of the genes that may be pertinent to plasma cell differentiation are discussed here.

Polyadenylation of mRNA is a complex process that requires multiple protein factors, including 3 cleavage stimulation factors (CSTF1, CSFT2 and CSTF3). It has been shown that the concentration of CSTF2 increases during B cell activation, and this is sufficient to switch IgM heavy chain mRNA expression from membrane-bound form to secreted form. The CSTF2 gene was expressed at low levels in tonsil B cells, but was turned off in tonsil and bone marrow plasma cells, indicating that CSTF2 gene expression can also be used to define plasma cell differentiation.

The gene for CD63 showed a progressive increase in gene expression across the three cell types studied. CD63 belongs to the transmembrane 4 super family (TM4SF) of membrane proteins. Expression has been found on the intracellular lysosomal membranes of hemopoietic precursors in bone marrow, macrophages, platelets, and Wiebel-Palade bodies of vascular endothelium. Importantly, CD63 was described as a marker for melanoma progression and regulates tumor cell motility, adhesion, and migration on substrates associated with β1 integrins.

Most importantly, the discovery of novel genes reported herein will lead to a broader knowledge of the molecular mechanisms involved in plasma cell differentiation. Specifically, of the top 50 EDGs, most were down-regulated, and a majority of the EDGs were transcription factors, suggesting that transcriptional regulation is an important mechanism for modulating differentiation. Among the LDGs, transcription factor representation was much lower than among the EDGs.

Cell Cycle Control and Programmed Cell Death

Consistent with the terminal differentiation of plasma cells, many genes involved in cell cycle control and DNA metabolism were down-regulated EDGs. The modulation of DNA ligase LIG1; repair enzymes MSHC, and RPA1, CDC20; and the cyclins CCNG2 and CCNF may have important consequences in inducing the quiescent state of plasma cells. The telomeric repeat binding protein TERF2, which is one of two recently cloned mammalian telomere binding protein genes, was a down-regulated EDG. TERF2 acts to protect telomer ends, prevents telomere end-to-end fusion, and may be important in maintaining genomic stability. It is of interest to determine if TERF2 is down-regulated during the terminal differentiation of all cell types, and whether the lack of this gene product in tumors of terminally differentiated cells results in the high degree of chromosome structural rearrangements which is a hallmark of multiple myeloma that lacks TERF2 gene expression (unpublished data).

The CDC28 protein kinase 2 gene CKS2, which binds to the catalytic subunit of the cyclin dependent kinases and is essential for their biological function, was the only cell cycle gene in the LDG genes. It was expressed in tonsil plasma cells that are capable of modest proliferation; however, CKS2 was completely extinguished in bone marrow plasma cells. Thus, shutting down CKS2 expression may be critical in ending the proliferative capacity of bone marrow plasma cells.

A distinguishing feature of plasma cell terminal differentiation is the acquisition of increased longevity in the bone marrow plasma cells. It is likely that this phenomenon is controlled through programmed cell death or apoptosis. The finding that anti-apoptotic and pro-apoptotic genes, BCL2 and BIK, demonstrated opposing shifts in expression is consistent with these two genes playing major roles in extending the life-span of bone marrow plasma cells.

Transcription Factors

The majority of differentially expressed genes belong to the transcription factor family. Of the 50 EDGs, only 7 were up-regulated. IRF4 and XBP1, two genes known to be up-regulated during plasma cell differentiation were in this group. Both genes were expressed at equal levels in the tonsil and bone marrow plasma cells, suggesting that a continual increase in expression of these important regulators does not occur. Although not on the HuGenFL Microarray, recent studies using third generation AFFYMETRIX U95Av2 microarray have also revealed an induction of Blimp-1 (PRDM1) expression in plasma cells compared with tonsil B cells (unpublished data), confirming the expected patterns of these transcription factors.

The vast majority of EDGs were down-regulated and the single largest subgroup of EDGs represented transcription factors (13 of 43 genes). Four of the 13 transcription factors, ETS1, SPI1, SPIB, and ELF1, belong to the ets family. These results are consistent with previous studies showing that several of the ETS proteins (ETS1, ELF1, PU.1 (SPI1), and SPI-B) are expressed in the B cell lineage. It is interesting to note that the down-regulation of ETS1 in the transition between tonsil B cell to tonsil plasma cell may be an important switch, as ETS1 knock-out mice show dramatic increases in plasma cells in the spleen and peripheral blood. In addition, it is curious that although SPI1 (PU.1) interacts with IRF4 in Blimp-1⁺ germinal center tonsil B cells and plasma cells, data presented herein show that whereas IRF4 is up-regulated in the plasma cell transition, SPI1 is shut down in tonsil and bone marrow plasma cells. Thus, these data support the notion that the ets family of transcription factors are important hematopoietically and that down-regulation of at least four family members appears to be an important event in terminal differentiation of plasma cells.

The cytoskeletal gene vinculin (VCL) and the MAP kinase-interacting serine/threonine kinase 1 gene (MKNK1) represented novel EDGs. Vinculin is thought to function in anchoring F-actin to the membrane, whereas MKNK1 is an ERK substrate that phosphorylates eIF4e after recruitment to the eIF4F complex by binding to eIF4G. These two genes were turned off in the tonsil B cell to tonsil plasma cell transition, but were reactivated in bone marrow plasma cells. The MYC proto-oncogene also showed a dramatic down-regulation in the tonsil B cell to tonsil plasma cell transition with reactivation in bone marrow plasma cells. It will be important to understand if these two genes are regulated either directly or indirectly by MYC. One of the mechanisms by which PRDF1-BF1 promotes generation of plasma cells is repression of MYC, thereby allowing the B cells to exit the cell cycle and undergo terminal differentiation. Instant study showing the extinguishing of MYC in the tonsil B cell to tonsil plasma cell transition is consistent with this data. The reactivation of MYC in bone marrow plasma cells to levels similar to those seen in tonsil B cells, which appear to be highly proliferative blasts, is unresolved but suggests that MYC may have dual roles.

Similar to the tonsil B cell to tonsil plasma cell transition, the majority of the transcription factors were down-regulated in the tonsil to bone marrow plasma cell transition. The BCL6 gene, although not in the top 50 significant EDGs, did make the top 50 list for LDGs. BCL6 did show a progressive loss of expression from tonsil B cells to tonsil plasma cells (see Table 14), but there was then a dramatic loss of expression in bone marrow plasma cells. Additional transcription factors, the myb-like gene MYBL1, and the MADS box factor MEF2B, were also turned off in bone marrow plasma cells and may be major regulators of the terminal stages of plasma cell differentiation. The transcription elongation factor TCEA1 was down-regulated but remained present. BMI1, a member of a vertebrate Polycomb complex that regulates segmental identity by repressing HOX genes throughout development, showed a significant progressive increase in expression across all groups. It is of note that BMI1 is the human homolog of the mouse Bmi-I proto-oncogene originally discovered as cooperating with transgenic c-Myc in inducing B cell lymphomas.

Given the recognition that changes in levels of expression of transcription factors represent the most striking feature of plasma cell differentiation, it is of interest to elucidate distinct pathways of transcriptional regulation driven by the various classes of transcription factors discovered herein. This can be done with the aid of global expression profiling and sophisticated data mining tools such as Baysian networks.

EXAMPLE 17

Identification of Genes with Similar Expression Between Multiple Myeloma and Cells at Different Stages of B Cell Development

Examples 17 and 18 describe the establishment of a B cell developmental stage-based classification of multiple myeloma using global gene expression profiling.

To classify multiple myeloma with respect to EDG and LDG reported above, 74 newly diagnosed cases of multiple myeloma and 7 tonsil B cell, 7 tonsil plasma cell, and 7 bone marrow plasma cell samples were tested for variance across the 359 EDGs and 500 LDGs disclosed above. The top 50 EDGs that showed the most significant variance across all samples were defined as early differentiation genes for myeloma (EDG-MM); likewise, the top 50 LDGs showing the most significant variance across all samples were identified as late differentiation genes for myeloma-1 (LDG-MM1). Subtracting the LDG-MM1 from the 500 LDG and then applying one-way ANOVA test for variance to the remaining genes identified the top 50 genes showing similarities between bone marrow plasma cells and multiple myeloma. These genes were defined as LDG-MM2.

Within the top 50 EDG-MM (Table 17), 18 genes that showed up-regulation in the tonsil B cell to tonsil plasma cell transition showed down-regulation to levels at or below that seen in tonsil B cells. The remaining 32 EDG-MM showed a reverse profile, in that these genes were down-regulated in the tonsil B cell to plasma cell transition, but showed tonsil B cell-like expression in multiple myeloma. In Table 17, gene expression was described as being at 1 of 5 possible levels. An absent absolute call (AAC), indicating an undetectable or absent gene transcript, was defined as “−”. For all the samples in a group, expression levels were defined as “+” if the gene transcript was present and the average difference (AD) was <1000, “++” for 1000≦AD<5000, “+++” for 5000≦AD<10,000, and “++++” for AD≧10,000.

One of the most striking genes defining EDG-MM was the cyclin dependent kinase 8 (CDK8), which was found absent in tonsil B cells but up-regulated to extremely high levels in tonsil and bone marrow plasma cells and then shut down again in virtually all multiple myeloma cases. The mitotic cyclin showed a progressive loss in expression from tonsil B cell (++) to tonsil plasma cell (+) to bone marrow plasma cell (−), whereas multiple myeloma cases either showing bone marrow-like levels or tonsil B cell levels. Given that the tonsil B cells used in this study likely represent highly proliferative centroblasts, multiple myeloma cases with similar levels might be suggestive of a proliferative form of the disease. A total of 27 of the top 50 EDG-MM showed no variability in multiple myeloma, ie, all multiple myeloma and tonsil B cell samples showed similar levels of expression.

A majority (34 of 50) of the top 50 LDG-MM1 (Table 18) were genes that showed up-regulation from the transition of tonsil plasma cell to bone marrow plasma cell, but showed down-regulation to tonsil plasma cell levels in multiple myeloma. The overall pattern seen for LDG-MM1 was the reverse seen for the EDG-MM, where a majority of those genes showed down-regulation from tonsil B cell to plasma cell and up regulation to tonsil B cell-like levels in multiple myeloma. The most dramatically altered LDG-MM1 was seen in the massive up-regulation of the CXC chemokines SDF1, PF4, and PPBP in bone marrow plasma cells in contrast with complete absence of detectable transcripts in all multiple myeloma. These results are validated by the fact that two separate and distinct probe sets interrogating different region of SDF1 (accession numbers L36033 and U 19495) were found to show identical patterns. The RB1 tumor suppressor gene showed a significant up-regulation in the tonsil plasma cell (+) to bone marrow plasma cell (++) transition with multiple myeloma showing levels consistent with either cell type. Unlike with the EDG-MM, only 15 of the top 50 LDG-MM1 showed no variability within the multiple myeloma population.

The LDG-MM2 genes (Table 19) showing similarities between bone marrow plasma cells and subsets of multiple myeloma revealed that all genes showed variability within multiple myeloma and that the variability could be dramatic, e.g. the apoptosis inhibitor BIK. Unlike those seen in EDG-MM and LDG-MM1, a large class of LDG-MM2 represented genes coding for enzymes involved in metabolism with a majority involved in glucose metabolism.

TABLE 17 EDG-MM: Tonsil B Cell-like Multiple Myeloma Genes Quantitative Gene Expression Accession Symbol Function TBC TPC BPC MM D28364 ANXA2 annexin family − + + −/+  U81787 WNT10B signaling; ligand − + ++ −/++ U88898 LOC51581 ^(a) unknown − + + −/+  X12451 CTSL protease; cysteine − ++ ++ − Z25347 CDK8 cell cycle; kinase − ++++ ++++ −/++ D38548 KIAA0076 ^(a) unknown + ++ ++ +/++ D86479 AEBP1 extracellular matrix + ++ ++ + U04689 OR1D2 signaling; receptor + ++ + + M31328 GNB3 signaling; G protein + ++ ++ + U13395 WWOX metabolism; + ++ ++ + oxidoreductase X14675 BCR signaling; GTPase for RAC + ++ ++ + X16665 HOXB2 transcription; homeobox + ++ ++ −/+  domain Z11899 POU5F1 transcription; homeobox + ++ ++ + domain Z36531 FGL2 secreted fibrinogen-like + ++ ++ + X80907 PIK3R2 signaling; kinase adaptor + +++ +++ ++ D31846 AQP2 aquaporin ++ +++ +++ ++ L18983 PTPRN phosphatase; membrane ++ ++++ ++++ ++ M23323 CD3E signaling; TCR partner ++ ++++ ++++ ++ D83781 KIAA0197 ^(a) unknown + − − + HT4824 CBS metabolism; cystathionine- + − − −/++ beta-synthase S78873 RABIF signaling; GTP releasing + − − +/++ factor U32645 ELF4 transcription; ets domian + − − −/+  X97630 EMK1 signaling; kinase; ELK + − − + domain Z24724 UNKNOWN ^(a) cell cycle + − − +/++ D16480 HADHA mitochondrial oxidation ++ − − −/++ L77701 COX17 mitochondrial oxidation ++ − − −/++ M90356 BTF3L2 transcription; NAC domain ++ − − ++ U08815 SF3A3 spliceosome ++ − − +/++ U53225 SNX1 intracellular trafficking ++ − − +/++ M25753 CCNB1 cell cycle ++ + − −/++ D87448 TOPBP1 ^(a) topoisomerase II binding ++ + + +/++ protein L38810 PSMC5 26S proteasome subunit 5 ++ + + ++ M29551 PPP3CB signaling; calcium dependent ++ + + +/++ phosphatase M32886 SRI signaling; calcium binding ++ + + ++ U24704 PSMD4 26S proteasome subunit 4 ++ + + ++ U25165 FXR1 RNA binding protein ++ + + ++ U37022 CDK4 cell cycle; kinase ++ + + ++ U53003 C21orf33 unknown; highly conserved ++ + + ++ X89985 BCL7B actin crosslinking ++ + + ++ D49738 CKAP1 tubulin folding +++ + + ++ D43950 CCT5 chaperonin +++ ++ ++ +++ D82348 ATIC metabolism; purine +++ ++ ++ +++ biosynthesis D86550 DYRK1A signaling; kinase +++ ++ ++ +++ L06132 VDAC1 anion channel +++ ++ ++ ++/+++ L43631 SAFB nuclear scaffold factor +++ ++ ++ ++/+++ M30448 CSNK2B signaling; casein kinase +++ ++ ++ ++/+++ regulation X76013 QARS metabolism; glutaminyl +++ ++ ++ ++/+++ tRNA synthetase D83735 CNN2 actin binding ++++ ++ ++ ++/+++ M86667 NAP1L1 nucleosome assembly ++++ ++ ++ +++ X04828 GNAI2 signaling; G protein ++++ ++ ++ ++/+++ Genes identified by one-way ANOVA analysis. Accession = GENBANK accession number. Symbol = HUGO approved gene symbol; unapproved symbol marked by ^(a). TBC, tonsil B cells; TPC, tonsil plasma cells; BPC, bone marrow plasma cells; AC, absolute call; AD, average difference. Quantitative gene expression: −, AC absent; +, AC present and AD < 1,000; ++, AD = 1,000 to 5,000; +++, AD = 5,000 to 10,000; ++++, AD > 10,000.

TABLE 18 LDG-MM1: Tonsil Plasma Cell-Like Multiple Myeloma Genes Quantitative Gene Expression Accession Symbol Function TPC BPC MM U90902 23612 ^(a) unknown; related to TIAM1 − + −/++ D12775 AMPD3 metabolism; AMP deaminase − + −/++ U37546 BIRC3 signaling; anti-apoptosis − ++ −/++ Z11793 SEPP1 metabolism; selenium transport − +++ −/+  L36033 SDF1 signaling; cxc chemokine − +++ − U19495 SDF1 signaling; cxc chemokine − +++ − M27891 CST3 protease inhibitor − ++++   −/++++ M26602 DEFA1 immunity − ++++   −/++++ M25897 PF4 signaling; cxc chemokine − ++++ − M54995 PPBP signaling; cxc chemokine − ++++ − U79288 KIAA051 ^(a) unknown + ++ +/++ M59465 TNFAIP1 signaling; anti-apoptosis + ++   +/++++ X53586 ITGA6 adhesion + ++ +/++ D50663 TCTEL1 dynein light chain + ++ +/++ U40846 NAGLU metabolism; hepran sulfate + ++ +/++ degradation M80563 S100A4 Signaling; calcium binding + ++   +/++++ X04085 CAT metabolism; catalase + ++ +/++ L02648 TCN2 metabolism; vitamin B12 + ++ + transport L35249 ATP6B2 lysosome; vacuolar proton + ++ + pump L09209 APLP2 amyloid beta precursor like + ++ + L41870 RB1 cell cycle + ++ +/++ X76732 NUCB2 signaling; calcium binding + +++  +/+++ D29805 5B4GALT1 adhesion + +++ + M29877 FUCA1 lysosome; fucosidase + +++ +/++ M32304 TIMP2 metalloproteinase 2 inhibitor + +++   +/++++ D10522 MACS actin crosslinking + ++++ −/++ L38696 RALY ^(a) RNA binding ++ +++ ++ U05875 IFNGR2 signaling; interferon gamma ++ +++ ++/+++ receptor U78095 SPINT2 protease inhibitor; blocks HGF ++ +++  −/+++ L13977 PRCP lysosomal; angiotensinase C ++ ++++ ++ U12255 FCGRT IgG Fc receptor ++ ++++  −/+++ L06797 CXCR4 signaling; SDF1 receptor ++ ++++  ++/++++ D82061 FABGL metabolism ++ ++++ ++/+++ Y00433 GPX1 oxidation protection +++ ++++ ++/+++ M60752 H2AFA histone; nucleosome + − −/++ U18300 DDB2 DNA repair + − + X63692 DNMT1 DNA methyltransferase + − + D11327 PTPN7 signaling; phosphatase ++ − ++ X54942 CKS2 cell cycle; kinase regulator ++ −  +/+++ D14874 ADM adrenomedullin ++ +   +/++++ D86976 KIAA0223 ^(a) minor histocompatability ++ +  +/+++ antigen X52979 SNRPB mRNA splicing ++ + +/++ Z49254 MRPL23 mitochondrial ribosomal protein ++ + ++ U66464 HPK1 signaling; kinase ++ + +/++ U91903 FRZB signaling; WNT antagonists ++ + +/++ D87453 MRPS27 mitochondrial ribosomal protein ++ + +/++ X59932 CSK signaling; kinase +++ ++ ++ L17131 HMGIY transcription; high mobility ++++ +  ++/++++ group L19779 H2AFO histone; nucleosome ++++ ++ ++++ U70439 SSP29 ^(a) unknown ++++ +++ +++/++++ Genes identified by one-way ANOVA analysis. Accession = GENBANK accession number. Symbol = HUGO approved gene symbol; unapproved symbol marked by ^(a). TPC, tonsil plasma cells; BPC, bone marrow plasma cells; AC, absolute call; AD, average difference. Quantitative gene expression: −, AC absent; +, AC present and AD < 1,000; ++, AD = 1,000 to 5,000; +++, AD = 5,000 to 10,000; ++++, AD > 10,000.

TABLE 19 LDG-MM2: Bone marrow Plasma Cell-Like Multiple Myeloma Genes Quantitative Gene Expression Accession Symbol Function BPC MM U61145 EZH2 transcription; SET domain − −/+  HT4000 SYK signaling; lymphocyte kinase − −/++ X89986 BIK signaling; apoptosis inducer −   −/++++ D85181 SC5DL metabolism; sterol-C5-desaturase + −/+  M98045 FPGS metabolism; folylpolyglutamate + −/++ synthase L41559 PCBD transcription; enhances TCF1 activity + −/++ L25876 CDKN2 cell cycle; CDK inhibitor; phosphatase + +/++ U76638 BRAD1 transcription; BRCA1 heterodimer + +/++ L05072 IRF1 transcription; IRF family + +/++ D87440 KIAA025 ^(a) unknown + +/++ U02680 PTK9 tyrosine kinase + +/++ U28042 DDX10 oncogene; ATP-dependent RNA + +/++ helicase L20320 CDK7 cell cycle; kinase + +/++ X56494 PKM2 metabolism; pyruvate kinase +   +/++++ M12959 TCRA signaling; T cell receptor ++ −/++ HT3981 INSL3 signaling; insulin-like peptide; IGF ++ −/++ family U21931 FBP1 metabolism; fructose bisphophatase ++   −/++++ Z48054 PXR1 metabolism; peroxisome biogenesis ++ +/++ D84145 WS-3 ^(a) dynatin 6 ++ +/++ D14661 KIAA00105 ^(a) transcription; WT1-associating protein ++ +/++ X77548 NCOA4 transcription; nuclear receptor ++ +/++ coactivator M90696 CTSS cysteine protease ++ +/++ D11086 IL2RG cytokine receptor ++ +/++ U70426 RGS16 signaling; GTPase activating protein ++  +/+++ X14850 H2AX histone; required for antibody ++  +/+++ maturation M29927 OAT metabolism; ornithine aminotransferase ++  +/+++ S74017 NFE2L2 transcription; ++  +/+++ HT4604 GYG metabolism; glycogen biogenesis ++  +/+++ M55531 SLC2A5 metabolism; fructose transporter ++   +/++++ M60750 H2BFL histone; nucleosome ++   +/++++ L19437 TALDO1 metabolism; transaldolase ++ ++/+++ M10901 NR3C1 transcription; glucocorticoid receptor ++ ++/+++ L41887 SFRS7 MRNA splicing factor ++ ++/+++ M34423 GLB1 metabolism; galactosidase ++  ++/++++ X15414 AKR1B1 metabolism; aldose reductase +++   +/++++ J04456 LGALS1 signaling; inhibits CD45 phosphatase +++   +/++++ X92493 PIP5K1B signaling; kinase +++   +/++++ U51478 ATP1B3 Na+, K+ transporter +++  ++/++++ X91257 SARS seryl-tRNA synthetase +++  ++/++++ D30655 EIF4A2 translation initiation +++  ++/++++ D31887 KIAA0062 ^(a) unknown +++  ++/++++ X04106 CAPN4 cysteine protease; calcium dependent +++  ++/++++ D87442 NCSTN ^(a) nicastrin +++  ++/++++ L76191 IRAK1 signaling; cytokine receptor kinase +++ +++/++++ HT1428 HBB hemoglobin ++++   −/++++ U44975 COPEB oncogene; transcription factor ++++   −/++++ X55733 EIF4B translation initiation ++++   +/++++ L09604 PLP2 signaling; colonic epithelium ++++   +/++++ differentiation HT1614 PPP1CA signaling; phosphatase ++++ +++/++++ L26247 SUI1 ^(a) translation initiation; probable ++++ +++/++++ Accession = GENBANK accession number or TIGR database. Symbol = HUGO approved gene symbol; unapproved symbol marked by ^(a). BPC, bone marrow plasma cells; AC, absolute call; AD, average difference. Quantitative gene expression: −, AC absent; +, AC present and AD < 1,000; ++, AD = 1,000 to 5,000; +++, AD = 5,000 to 10,000; ++++, AD > 10,000.

EXAMPLE 18

Hierarchical Cluster Analysis with EDG-MM, LDG-MM1, and LDG-MM2 Reveals Developmental Stage-Based Classification of Multiple Myeloma

To identify whether variability in gene expression seen in multiple myeloma (MM) might be used to discern subgroups of disease, hierarchical cluster analysis was performed on 74 newly diagnosed MM, 7 tonsil B cell, 7 tonsil plasma cell, and 7 bone marrow samples using the EDG-MM (FIG. 18), LDG-MM1 (FIG. 19), and LDG-MM2 (FIG. 20). Hierarchical clustering was applied to all samples using 30 of the 50 EDG-MM. A total of 20 genes were filtered out with Max−Min<2.5. This filtering was performed on this group because many of the top 50 EDG-MM showed no variability across MM and thus could not be used to distinguish MM subgroups. A similar clustering strategy was employed to cluster the samples using the 50 LDG-MM1 and 50 LDG-MM2.

The MM samples clustering with the tonsil B cell samples were then identified to determine whether the MM cases clustering with tonsil B cells, or tonsil and bone marrow plasma cells could be correlated with gene expression-defined MM subgroups (Table 20). This data showed that of the MM cases clustering tightly with the tonsil B cell samples, 13 of 22 were from the MM4 subgroup, accounting for a majority of all MM4 cases (13 of 18 MM4 samples). The LDG-MM defined cluster distribution of gene expression-defined MM subgroups was dramatically different in that 14 of the 28 MM samples clustering with the tonsil plasma cell samples were from MM3 subgroup (14 of 15 MM3 samples). LDG-MM2 again showed a strong correlation with the MM subgroups in that 14 of the 20 MM cases in this cluster were from the MM2 subgroup (14 of 21 MM2 cases). Thus, the MM4, MM3, and MM2 subtypes of MM have similarities to tonsil B cells, tonsil plasma cells, and bone marrow plasma cells respectively. MM1 represented the only subgroup with no strong correlations with normal cell counterparts tested here, suggesting that this class has unique characteristics yet to be uncovered.

The distribution of the four MM subgroups in the normal cell cluster groups was determined next (Table 21). The results demonstrate that whereas all MM3 cases were able to be classified, 6 MM1, 5 MM2, and 3 MM4 cases were not clustered with any normal cell group in any of the three cluster analyses. In all samples capable of being clustered, there were strong correlations between gene expression-defined subgroups and normal cell types with the exception of MM1. The data also show that 3 MM1, 2 MM2, 4 MM3, and 1 MM4 cases were found to cluster in two groups. No samples were found in three groups and all cases clustering with two normal classes were always in an adjacent, temporally appropriate groups. P241 was an exception in that it was clustered in the bone marrow plasma cell and tonsil B cell groups.

Because one of the EDG-MMs was discovered to be cyclin B1 (CCNB1) (Table 17), it was determined if a panel of proliferation association genes recently discovered to be up-regulated in MM4 could be used to advance and validate the classification of MM4 as a so-called tonsil B cell-like form of MM. Box plots of the expression patterns of CCNB1, CKS1, CKS2, SNRPC, EZH2, KNSL1, PRKDC, and PRIM1 showed significant differences across all the groups tested with strong significant correlation between tonsil B cells and MM4 (FIG. 21). Several important observations were made in this analysis. For all the genes, with the exception of SNRPC, there was a progressive reduction in expression in the transition from tonsil B cells to tonsil plasma cells to bone marrow plasma cells. In addition, striking correlations were observed with PRIM1 (FIG. 21). Although PRIM1 expression was significantly different across the entire group (p=4.25×10⁻⁵), no difference exists between tonsil B cells and MM4 (Wilcoxon rank sum [WRS] p=0.1), or between tonsil plasma cells and MM3 (WRS p=0.6). Given the important function of several transcription factors in driving and/or maintaining plasma cell differentiation, it was determined if these factors showed altered expression across the groups under study. Although other factors showed no significant changes, XBP1 (FIG. 21) showed an enormous up-regulation between tonsil B cells and tonsil plasma cells as expected. However, the gene showed a reduction in bone marrow plasma cells and a progressive loss across the four MM subgroups with MM4 showing the lowest level (p=3.85×10⁻¹⁰).

Based on conventional morphological features, plasma cells have been thought to represent a homogeneous end-stage cell type. However, phenotypic analysis and gene expression profiling disclosed herein demonstrated that plasma cells isolated from distinct organs can be recognized as belonging to distinct stages of development. Multiple myeloma plasma cells are derived from the bone marrow and are thought to represent a transformed counterpart of normal terminally differentiated bone marrow plasma cells. However, the dramatic differences in survival, which can range from several months to greater than 10 years, suggests that multiple myeloma may represent a constellation of several subtypes of disease. Conventional laboratory parameters have not been particular useful in segregating distinct disease subtypes with sufficient robustness that would allow adequate risk stratification. In addition, unlike achievements in classifying leukemias and lymphomas based on similar nonrandom recurrent chromosomal translocations, the extreme karyotypic heterogeneity of multiple myeloma has made attempts at understanding the molecular mechanisms of the disease and classification prediction virtually impossible.

In studies presented here, it was identified that many EDGs and LDGs exhibit highly variable expression in multiple myeloma, suggesting that multiple myeloma might be amenable to a developmental stage-based classification. It appears from the results of this study that multiple myeloma can in fact be classified based on similarities in gene expression with cells representing distinct stages of B cell differentiation. This developmental based-system in conjunction with the gene expression-based system reported above represents a critical affirmation of the validity of the developmental-based system.

Recent studies provide support for the hypothesis that MM3 represents a tonsil plasma cell-like form of the disease. Microarray profiling with the U95Av2 GENECHIP on 150 newly diagnosed patients (including the 74 described here) along with an analysis of chromosome 13 loss has revealed a significant link between reduced RB1 transcripts with either monosomy or partial deletions of chromosome 13 (unpublished data). In these studies, it was observed that a number of multiple myeloma cases with or without chromosome 13 deletion had RB1 transcripts at levels comparable to those seen in normal tonsil plasma cells. FISH analysis with a bacterial artificial chromosome BAC covering RB1 demonstrated that these cases did not have interstitial deletions of the RB1 locus. Given that RB1 was found to be a LDG-MM1, it was determined if the low levels of RB1 may be linked to tonsil plasma cell-like MM, i.e MM3. Of 35 multiple myeloma cases with RB1 AD values of <1100 (RB1 AD value not less than 1100 in 35 normal bone marrow plasma cell samples tested), 74% belonged to the MM3 class. In contrast, of 38 multiple myeloma cases lacking deletion 13 and having RB1 AD values greater than 1100, only 21% belonged to the MM3 subtype (unpublished data).

Although there is a significant link between the cell development-based classification and gene expression profiling-based classification disclosed herein, there are exceptions in that although as expected the majority of the MM4 cases belonged to the tonsil B cell-cluster subgroup, 5 MM3, 1 MM2, and 3 MM1 cases were also found in this cluster. The recognition that cases within one gene expression-defined subgroup could be classified in two normal cell defined clusters suggests these cases may have intermediate characteristics with distinct clinical outcomes. It is of interest to determine if the unsupervised gene expression-based system or developmental stage-based system alone or in combination will allow the creation of robust risk stratification system. This can be tested by allowing sufficient follow-up time on >150 uniformly treated multiple myeloma cases in which profiling has been performed at diagnosis.

MM1 was the only gene expression-defined subgroup lacking strong similarities to any of the normal cell types analyzed in this study. It is possible that MM1 has similarities to either mucosal-derived plasma cells or peripheral blood plasma cells which has recently been shown to represent a distinct type of plasma cells. Future studies will be aimed at providing a developmental stage position for this subtype.

The hypoproliferative nature of multiple myeloma, with labeling indexes in the clonal plasma cells rarely exceeding 1%, has lead to the hypothesis that multiple myeloma is a tumor arising from a transformed and proliferative precursor cell that differentiates to terminally differentiated plasma cells. It has been shown that there is a bone marrow B cell population transcribing multiple myeloma plasma cell-derived VDJ joined to IgM sequence in IgG- and IgA-secreting multiple myelomas. Other investigations have shown that the clonogenic cell in multiple myeloma originates from a pre-switched but somatically mutated B cell that lacks intraclonal variation. This hypothesis is supported by recent use of single-cell and in situ reverse transcriptase-polymerase chain reaction to detect a high frequency of circulating B cells that share clonotypic Ig heavy-chain VDJ rearrangements with multiple myeloma plasma cells. Studies have also implicated these precursor cells in mediating spread of disease and affecting patient survival.

Links of gene expression patterns between subsets of multiple myeloma and cells representing different late stages of B cell differentiation further support the above hypothesis in that MM4 and MM3 may have origins in a so called “multiple myeloma stem cell”. This hypothesis can be tested by isolating B cells from tonsils or lymph nodes or peripheral blood of MM3 and MM4 patients, differentiating them into plasma cells in vitro using a new method described (9) and then testing for the presence of an multiple myeloma gene expression signature within the differentiated populations. Even if the multiple myeloma stem cell represents a minority population in the B cells, the multiple myeloma gene expression signature may be recognized, if not with conventional microarray, then by more sensitive quantitative real-time RT-PCR. A real time RT-PCR method is envisioned as expression profile models using at little as 20 genes that distinguish malignant multiple myeloma plasma cells from normal plasma cells at an accuracy of 99.5% have been developed (unpublished data).

Regardless of the outcome of these experiments, it is clear that gene expression profiling has become an extremely powerful tool in evaluating the molecular mechanisms of plasma cell differentiation and how these events relate to multiple myeloma development and progression, which in turn should provide more rational means of treating this currently fatal disease.

TABLE 20 Distribution of Multiple Myeloma Subgroups in Hierarchical Clusters Defined by EDG-MM, LDG-MM1, and LDG-MM2 Genes Gene Expression-Defined MM Subgroups MM1 MM2 MM3 MM4 Normal Cluster n = 20 n = 21 n = 15 n = 18 p EDG-MM n = 22 3 1 5 13 .00005 LDG-MM1 n = 29 8 4 14 3 .000008 LDG-MM2 n = 20 6 14 0 0 .000001

TABLE 21 Distribution of Gene Expression-Defined Multiple Myeloma Subgroup Cases in Normal Cell Clusters defined by EDG-MM, LDG-MM1, and LDG-MM2 MM1 TBC TPC BPC MM2 TBC TPC BPC MM3 TBC TPC BPC MM4 TBC TPC BPC P026 Y Y P237 Y Y P052 Y Y P034 Y Y P037 Y Y P241 Y Y P098 Y Y P051 Y P029 Y Y P079 Y P107 Y Y P057 Y P061 Y P083 Y P158 Y Y P063 Y P066 Y P121 Y P119 Y P065 Y P006 Y P144 Y P221 Y P075 Y P120 Y P157 Y P030 Y P084 Y P131 Y P171 Y P043 Y P122 Y P002 Y P176 Y P053 Y P127 Y P010 Y P213 Y P055 Y P154 Y P067 Y P215 Y P138 Y P187 Y P226 Y P251 Y P155 Y P199 Y P025 Y P250 Y P163 Y P255 Y P082 Y P222 Y P239 Y P054 Y P085 P103 Y P175 Y P101 Y P099 P202 Y P056 P001 P015 P091 P016 P048 P168 P036 P124 P118 P212 P249 MM1, MM2, MM3, MM4, and PXXX represent gene expression-defined subgroups and patient identifiers, respectively. Y indicates that the case was found in the normal cell-defined cluster. Cases in italics were not found to cluster with any normal cell type. Some cases were found to cluster with two normal cell types. TBC, tonsil B cells; TPB, tonsil plasma cells; BPC, bone marrow plasma cells.

EXAMPLE 19

Diagnostic Models that Distinguish Multiple Myeloma, Monoclonal Gammopathy of Undetermined Significance, and Normal Plasma Cells

The molecular mechanisms of the related plasma cell dyscrasias monoclonal gammopathy of undetermined significance (MGUS) and multiple myeloma (MM) are poorly understood. Additionally, the ability to differentiate these two disorders can be difficult. This has important clinical implications because MGUS is a benign plasma cell hyperplasia whereas MM is a uniformly fatal malignancy. Monoclonal gammopathies are characterized by the detection of a monoclonal immunoglobulin in the serum or urine and underlying proliferation of a plasma cell/B lymphoid clone. Patients with MGUS have the least advanced disease and are characterized by a detectable plasma cell population in the marrow (<10%) and secretion of a monoclonal protein detectable in the serum (<30 g/L), but they lack clinical features of overt malignancy (such as lytic bone lesions, anemia, or hypercalcemia). Patients with overt MM have increased marrow plasmacytosis (>10%), serum M protein (>30 g/L), and generally present with anemia, lytic bone disease, hypercalcemia, or renal insufficiency.

Approximately 2% of all monoclonal gammopathy of undetermined significance cases will convert to overt multiple myeloma per year, but it is virtually impossible to predict which of these cases will convert. A difficulty in the clinical management of multiple myeloma is the extreme heterogeneity in survival, which can range from as little as two months to greater than eight years with only 20% of this variability being accounted for with current clinical laboratory tests. Thus, there is a great need for more robust methods of classification and stratification of these diseases.

This example reports on the application of a panel of statistical and data mining methodologies to classify multiple myeloma (MM), monoclonal gammopathy of undetermined significance (MGUS), and normal plasma cells. Expressions of 12,000 genes in highly purified plasma cells were analyzed on a high density oligonucleotide microarray. Various methodologies applied to global gene expression data identified a class of genes whose altered expression is capable of discriminating normal and malignant plasma cells as well as classifying some MGUS as “like” MM and others as “unlike” MM. The extremely high predictive power of this small subset of genes, whose products are involved in a variety of cellular processes, e.g., adhesion and signaling, suggests that their deregulated expression may not only prove useful in the creation of molecular diagnostics, but may also provide important insight into the mechanisms of MM development and/or conversion from the benign condition of MGUS to the overly malignant and uniformly fatal MM.

Six different methodologies were employed herein: logistic regression, decision trees, support vector machines (SVM), Ensemble of Voters with 20 best information gain genes (EOV), naïve Bayes, and Bayesian networks. All six models were run on microarray data derived from AFFYMETRIX (version 5) high density oligonucleotide microarray analysis. One hundred fifty six untreated MM samples, 34 healthy samples, and 32 samples designated as MGUS were compared. The normalization algorithm available from the Affymetrix software was used. Information on normalization and standardization of the microarray data is available on Affymetrix's website.

Statistical and Data Mining Methodologies

Various methods were employed with two goals in mind. The first goal is to identify genes whose over or under expression are apparent in the comparison of healthy samples, MGUS (monoclonal gammopathy of undetermined significance) samples, and malignant MM (multiple myeloma) samples. The second goal is to identify optimal methods for use in analyzing microarray data and specifically methods applicable to analyzing microarray data on samples from MGUS and MM patients. Previous work has been done in identifying lists of genes that discriminate between the two types of samples (1, 10), but, to our knowledge, this is the first work that has been done on simultaneously identifying discriminatory genes and creating models to predict and describe the differences between myeloma, MGUS, and healthy samples.

For each of the methods (and each of the comparisons), a 10-fold cross validation was employed to estimate the prediction error. Using 10-fold cross validation, 1/10^(th) of the data was removed (the ‘test’ data), and the entire model was created using only the remaining 90% of the data (the ‘training’ data.) The test data were then run through the training model and any misclassifications were noted. Error rates were computed by compiling the misclassifications from each of the 10 independent runs. Empirical results suggest that 10-fold cross validation may provide better accuracy estimates than the more common leave one out cross validation (11).

Logistic Regression

The logistic procedure creates a linear model that yields a number between zero and one. This value represents a predictive probability, for example, of being in the multiple myeloma sample (predictive value close to one) or of being in the normal sample (predictive value close to zero). The structure allows for knowledge of the uncertainty in predicting the group membership of future samples. For example, a new sample might be classified with a predictive probability of 0.53 and classified as multiple myeloma, albeit with much less confidence than another sample whose predictive probability is 0.99.

Decision Trees

Decision tree induction algorithms begin by finding the single feature that is most correlated with class. For the present discussion, mutual information was used and the classes were multiple myeloma vs. normal, multiple myeloma vs. MGUS and MGUS vs. normal. For each feature, the algorithm computes the information gain of the detection and of the optimal split point for the real-valued measure (signal). Information gain is defined as follows: the entropy of a data set is—p log₂p−(1−p)log₂(1−p) where p is the fraction of samples that are of a certain class. A split takes one data set and divides it into two data sets: the set of data points for which the feature has a value below the split point (or a particular nominal value) and the set of data points for which the gene has a value above the split point (or any other nominal value).

Ensembles Even with pruning, decision trees can sometimes over fit the data. One approach to avoid over fitting is to learn the n best simple decision trees, and let these trees vote on each new case to be predicted. The simplest decision tree is a decision stump, a decision tree with a single internal node, or decision node. Our “Ensemble of Voters” (EOV) approach is an unweighted majority vote of the top 20 decision stumps, scored by information gain. Naïve Bayes

Naïve Bayes is so named because it makes the (often) naïve assumption that all features (e.g. gene expression levels) are conditionally independent of the given class value (e.g. MM or normal). In spite of this naïve assumption, in practice it often works very well. Like logistic regression, naïve Bayes returns a probability distribution over the class values. The model simply takes the form of Bayes' rule with the naïve conditional independence assumption.

Bayesian Networks

Bayesian networks (Bayes nets) are a very different form of graphical model from decision trees. Like decision trees, the nodes in a Bayes net correspond to features, or variables. For classification tasks, one node also corresponds to the class variable. A Bayes net is a directed acyclic graph (DAG) that specifies a joint probability distribution over its variables. Arcs between nodes specify dependencies among variables, while the absence of arcs can be used to infer conditional independencies. By capturing conditional independence where it exists, a Bayes net can provide a much more compact representation of the joint distribution than a full joint table or other representation. There is much current research into the development of algorithms to construct Bayes net models from data (12-14). Bayes nets are proven to be outstanding tools for classification. For example, in KDD Cup 2001, an international data mining competition with over 100 entries, the Bayes net learning algorithm PowerPredictor was the top performer on a data set with strong similarities to microarray data (15). This is the algorithm employed in the present study.

Support Vector Machines

Support vector machines (SVMs) (16-17) are another novel data mining approach that has proven to be well suited to gene expression microarray data (18-19). At its simplest level, a support vector machine is an algorithm that attempts to find a linear separator between the data points of two classes. SVMs seek to maximize the margin, or separation between the two classes. Maximizing the margin can be viewed as an optimization task that can be solved with linear programming techniques. Support vector machines based on “kernel methods” can efficiently identify separators that belong to other functional classes. A commonly used kernel is the Gaussian kernel. Nevertheless, for gene expression microarray data, it has been repeatedly demonstrated empirically that simple linear SVMs give better performance (18-19) than SVMs with other kernels.

Results

As mentioned, each model was tested using 10-fold cross validation to obtain error (misclassification) rates. For each of 10 runs of the data, 10% of the sample was removed and the prediction model was created. Then, using the created model, the test sample was predicted into groups and the accuracy was recorded. After completing all 10 runs, the accuracy values were accumulated into Table 22.

There does not appear to be one methodology that stands out from the rest in terms of predicting group membership. In the difficult classification of multiple myeloma (MM) vs. MGUS, Ensemble of Voters classifies the most MGUS correctly (68.75%), but the fewest multiple myeloma correctly (57.69%.) Using naïve Bayes produces the best classification, though it does not seem to be appreciably better than the other methods. All the methods appear to be able to classify multiple myeloma vs. Normal quite well and MGUS vs. Normal almost as well.

To test the difference of accuracy across procedures, a paired t-test was done for the overall correct classification rate for each of the comparisons on each of the folds of the procedures. None of the methods were significantly different (p≦0.05) except the EOV when compared to the other methods in the MGUS vs. multiple myeloma test. The paired t-tests give p-values between 0.002 and 0.031 (unadjusted for multiple comparisons) for the EOV compared with the other 5 models in the MGUS vs. multiple myeloma test. According to this test, the EOV has a significantly lower rate of correct classification, though it is the most accurate MGUS classifier as shown above. In comparing two groups, this is often the trade off between sensitivity and specificity.

Models for predicting group membership were identified for each method. The models classifying multiple myeloma vs. MGUS had more overlapping genes (17 unique genes) then the models classifying multiple myeloma vs. Normal (12 unique genes) or MGUS vs. Normal (10 unique genes.) A possible explanation for this is that there are probably numerous genes that distinguish multiple myeloma and normal samples because the two groups are quite distinct. However, the genetic similarities between multiple myeloma and MGUS lead to fewer number of genes that are different across the two groups. This dearth of distinguishing genes conditions any good model to contain some of the same limited number of genes. A more detailed discussion of the particular genes is given in the conclusion.

Meta-Voting

As an additional step to improve the prediction capabilities of the method, a “meta” the marginal predicted group was calculated and then a final prediction was given as the top voted group. A sample is classified in a group if at least two of the three methods predict that group. The calculation indicate that the meta voting procedure does not improve the results.

Receiver Operator Characteristic (ROC) Curves

A Receiver Operating Characteristic (ROC) curve demonstrates the relationship between sensitivity (correct prediction to the more diseased group) and specificity (correct prediction to the less diseased group). FIG. 22 gives the ROC curves for the comparison of MM (multiple myeloma) vs. MGUS classification. The difficult comparison (multiple myeloma vs. MGUS) is challenging for all the methods. For example, naïve Bayes has a high sensitivity but at the cost of low specificity. For even mediocre values of specificity, the sensitivity drops off quite rapidly. In order to have a high sensitivity for any of the methods (that is, in order to have very few false positives of multiple myeloma), the ability to predict MGUS accurately (specificity) was compromised.

Prediction of MGUS

The models that classify the multiple myeloma and normal samples into distinct groups may also be able to be used as a predictive model for samples that are not clearly in either group based on clinical data. As a whole, the MGUS samples are clinically healthy (except for high levels of immunoglobulins) but genetically appear malignant. Applying the multiple myeloma vs. normal model to the MGUS samples will give us an idea as to which group the MGUS samples look more like. Table 23 provides the prediction distribution for the MGUS samples into the multiple myeloma and normal groups based on the model which compared multiple myeloma to normal samples. On average, about 90% of the MGUS samples are classified as multiple myeloma, and about 10% are classified as normal. The possible reason for this is that the 10% who are classified as normal may have longer survival times and less disease progression. Regardless, the similarity of MGUS to multiple myeloma (even in the model that was derived without any MGUS) gives additional evidence that the MGUS is actually genetically much more similar to the multiple myeloma than to the normal samples. From both the prediction of the dichotomous groups and the classification of MGUS samples into the two extreme groups, it can be concluded that the methods are not notably different.

In order to better understand the mechanisms behind the poor classification of the MGUS samples (when compared to multiple myeloma), the number of MGUS classified as multiple myeloma for each of three methods, logistic regression, SVM, and Bayes Net was tabulated. Of the 32 MGUS samples, the misclassification rates are given in Table 24. There were 26 MGUS samples misclassified using the logistic procedure; 17 of the 26 were also misclassified using SVM, and 18 of the 26 were misclassified using Bayes Net. This cross tabulation indicates that the misclassified MGUS samples are continuously getting misclassified which lends evidence to a possible subset of MGUS samples that are genetically similar to the multiple myeloma samples.

Discussion

Six different statistical and data mining algorithms were examined for their ability to discriminate normal, hyperplastic, and malignant cells based on the expression patterns of ˜12,000 genes. The models were highly accurate in distinguishing normal plasma cells from abnormal cells. However, these models displayed a uniform failure in the discrimination between the hyperplastic cells and malignant cells. A major goal of this study was to develop or modify data mining tools in order to capture a small subset of genes from massive gene expression data sets to accurately distinguish groups of cells, e.g. normal, precancerous, and cancerous cells, with the ultimate goal to create sensitive and reproducible molecular-based diagnostic tests. In addition, future studies can be aimed at using a similar strategy to identify a minimum subset of genes capable of discriminating subgroups of disease for risk stratification and prognostics. This is a particularly important concept for this disease as the overall survival in multiple myeloma is highly variable, with some patients surviving as long as 10 years while others die within several months of diagnosis. Current microarrray studies require the isolation of large numbers of cells that necessitate advanced facilities and expertise. The studies described in this example represent the first step toward streamlining this process, as a smaller subset of genes, e.g., 10-20, with a high predictive power allows for a massive reduction in scale, which in turn will make development of a commercial test more amenable to mass production and hence widespread clinical use.

One possible reason for the inability of the models to discriminate MGUS (monoclonal gammopathy of undetermined significance) from multiple myeloma is that MGUS represents at least two different diseases. This is supported by the overlap in misclassification of MGUS samples as shown in Tables 19-20. In simplistic terms, MGUS can be viewed as a disease that will remain indolent or one that will convert to overt malignancy. Accruing sufficient numbers of stable and progressive MGUS cases along with sufficient follow-up time will help resolve this issue.

The failure of the models to differentiate the two disease types could be related to the limitations of the current methodologies. The microarray profiling utilized here only interrogated ⅓ of the estimated 35,000 human genes (20-21), thus it is possible that a whole genome survey would reveal discriminating features. A new Affymetrix U133 GeneChip system which is thought to interrogate all human genes may be used to address this question. It is also possible that a whole genome analysis will reveal no significant differences. This revelation could mean any of a variety of possibilities: (1) there is no genetic difference between the two diseases, (2) only the MGUS that are classified as multiple myeloma are genetically similar to multiple myeloma, and the clinical tests are unable to identify that distinction, (3) the current microarray technology is not specific enough to measure the differences between the two diseases, (4) the methods described above are not appropriate for this type of analysis. If (1) or (2) is true, these results would point to other determinants of an indolent or malignant course such as genetic predisposition or somatic DNA mutations not manifest in gene expression, a unique environmental exposure interacting with these predisposing genetic traits, or a non-tumor cell microenvironment or “soil” that promotes plasma cell growth.

Another goal of this work was to use the models of global gene expression profiling to define critical genetic alterations that accompany the transition of a plasma cell from its normal homeostasis to a benign hyperplasia and from hyperplasia to an overt malignancy. Integration of the data from the six models revealed a group of genes that were found in two or more of the models. For purposes of this study these genes were interpreted to represent the most differentially expressed in these transitions. Ten common genes were identified in the normal to MGUS (monoclonal gammopathy of undetermined significance) comparison with 8 of the genes being down-regulated or shut down in the abnormal cells. A similar phenomenon was seen in the normal versus multiple myeloma comparison with 9 of 12 common genes being down-regulated. This was in contrast to the MGUS versus multiple myeloma comparison where almost half (8 of 18 probe sets representing 17 unique genes) of the probe sets were up-regulated in multiple myeloma. Probes sets for 4 different chemokine genes SCYA23 (Normal vs. MGUS), SDF1 (Normal vs. MM), and SCYC2 and SCYA18 (MGUS vs. MM) were down-regulated in the latter group in each of the 3 comparisons. Two probe sets for SCYA18 were found in the MGUS vs. MM comparison. This is an important validation of SCYA18 gene expression truly being different in the two conditions. Chemokines are important mediators of immune responses and act as soluble factors that induce the migration of specific immune cells to sites of inflammation. The potential significance of the loss of expression of multiple chemokine genes in plasma cell dyscrasias is not understood, but may point to how tumors may suppress anti-tumor immune reactions.

As with SCYA18, two unrelated probe sets for the human homologue of the Drosophila melangaster gene frizzled (FZD2) were down-regulated in the normal to MGUS transition. FZD2 codes for a membrane bound receptor that binds a highly conserved family of soluble ligands known as WNTs. WNT signaling regulates homeotic patterning and cell-fate decisions in multicellular organisms ranging from flies to humans. The Wnt signaling cascade has also been shown to be involved in neoplasia as hyperactivation of the Wnt-1 gene by viral insertional mutagenesis caused spontaneous mammary tumorigenesis in mice. It is suspected that loss of FZD2 expression in MGUS carries potential significance given that expression profiling has revealed deregulated expression of multiple members of the WNT signaling pathway in multiple myeloma and plasma cell leukemia (results shown above; (1, 22). Results in previous examples presented above also show that a secreted antagonist of WNT signaling, FRZB, exhibits elevated expression in a comparison of normal plasma cells and multiple myeloma (1, 22). The concomitant, or possibly sequential, down-regulation of the functional WNT receptor (FZD2) and up-regulation of a decoy receptor strongly suggests that disruption of WNT signaling plays a pathological role in multiple myeloma development. In addition to abnormalities in the receptor and decoy genes, the genes for the ligands, WNT5A and WNT10B, have been identified as altered in multiple myeloma (results shown above; (23)). Whereas WNT5A is upregulated in multiple myeloma, WNT10B is expressed at high levels in normal plasma cells but not in a majority of multiple myeloma plasma cells (1). It is of note that recent studies have demonstrated that Wnt-5A, Wnt-2B, Wnt-10B, Wnt-11 comprise a novel class of hematopoietic cell regulators.

Taken together these findings suggests that deregulated autocrine and/or paracrine Wnt signaling may play a pivotal role in plasma cell dyscrasias and that a progressive deregulation of multiple components of the signaling complex may be associated with disease progression from normal plasma cells to hyperplastic, but benign, MGUS then to overt multiple myeloma. In conclusion, it is anticipated that strategies like those employed here will allow the creation of new molecular diagnostic and prognostic tests and should provide useful insight into the genetic mechanisms of neoplastic transformation.

TABLE 22 Ten-Fold Cross Validation Results % correctly classified MM Normal MM MGUS MGUS Normal Logistic 98.72% 91.18%  89.1%  18.8% 90.63% 97.06% Trees 97.44% 94.12% 87.18%  37.5% 90.63% 94.12% SVM 98.72% 97.06% 89.10% 34.38% 90.63%  100% Bayes Net 98.72%  100% 93.56% 34.38% 90.63% 97.06% EOV 98.08%  100% 57.69% 68.75% 90.63%  100% Naïve Bayes 98.08%  100% 91.67% 43.75% 90.63%  100%

TABLE 23 MM vs. Normal (predicting MGUS) % MGUS classified as: MM Normal Logistic  87.5% 12.5% Trees 93.75% 6.25% SVM 93.75% 6.25% Bayes Net 93.75% 6.25% EOV 84.37% 15.63%  Naïve Bayes 93.75% 6.25%

TABLE 24 # MGUS misclassified Logistic SVM Bayes Net Logistic 26 17 18 SVM 21 17 Bayes Net 21

EXAMPLE 20

Elevated Expression of Wnt Signaling Antagonists DKK1 and FRZB In Myeloma Plasma Cells is Associated with Lytic Bone Disease

Multiple myeloma is the only hematological malignancy consistently associated with debilitating lytic bone disease. The prevalence of bone disease varies with the presentation of multiple myeloma, from smoldering multiple myeloma often without bone involvement, to solitary plasmacytoma, to diffuse or focal multiple myeloma where systemic losses of bone mineral density or focal lytic bone lesions are seen in 80% of patients. Progression from the pre-malignant monoclonal gammopathy of undetermined significance (MGUS) to overt multiple myeloma is preceded by changes in bone turnover rates. Bone loss tends to be located adjacent to malignant plasma cells, suggesting that multiple myeloma plasma cells secrete factors that induce osteoclast activation and/or suppress osteoblast growth and differentiation.

To identify secreted factors linked to multiple myeloma bone disease, the expression profiles of ˜12,000 genes was compared in CD138-enriched plasma cells (PC) from newly diagnosed multiple myeloma (MM) with no radiological evidence of osteolytic bone lesions (n=87) to those with ≧3 lytic lesions (n=83). Of a total of 367 genes identified, 229 were higher and 138 lower in PC from MM with lytic lesions. Expression of genes associated with cell proliferation, e.g. PCNA, TYMS, PRKDC, CENPA, and TOP2A predominated in MM with lytic lesions. In contrast ARHE, IL-6R, WNT10B, and the B-cell receptor molecules SLAM, TACI, and LNHR, were notable genes expressed at significantly lower levels in MM with lytic lesions. Consistent with a critical role of WNT signaling in osteoblast growth and differentiation (see below), the two secreted WNT signaling antagonists, soluble frizzled related protein 3 (SFRP-3/FRZB) and DKK1, represented the only genes coding for secreted factors within the top 50 up-regulated genes. Importantly, DKK1 and FRZB were not expressed in PC from 45 normal bone marrow donors or 10 Waldenstrom's macroglobulinemia, a PC malignancy that lacks bone disease, and monoclonal gammopathy of undetermined significance (MGUS). Both immuno-histochemistry and immunofluoresence of biopsy material confirmed gene expression data.

Since lytic bone lesions develop at sites of MRI-defined medullary plasmacytoma (MPCT), MRI represents a highly sensitive surrogate for present or future osteolytic lesions. As MRI-defined MPCT can be observed in the absence of x-ray detectable lytic lesions, it is hypothesized that those cases with no lytic lesions, yet having underlying MPCT might skew the data analysis when correlating gene expression with x-ray data alone. Thus, the inventors combined x-ray and MRI data and applied c², WRS, and SAM (significance analysis of microarrays) analyses to compare 65 newly diagnosed cases of MM exhibiting three or more lytic lesions and three or more MPCT with 43 cases exhibiting no lytic lesions or MPCT. A total of 107 genes differentiating the two groups at p<0.001 were identified. Importantly many of the same genes, e.g. cell cycle genes, identified above were also identified in the latter analysis and the levels of difference have increased. For example, whereas the ratio (bone disease/no bone disease) of the mean expression level for DKK1 in the first comparison was 2.45, the mean value increased to 6.25 in the latter. This reflected the fact that virtually all cases with no lytic lesions and moderate to high DKK1 had MRI-defined focal lesions. The mean expression level of DKK1 in the no lytic lesion group was 1674 (range 40 to 10828) whereas the mean DKK1 level in the no lytic lesion & no focal lesion group dropped to 625 (range 57 to 4183).

It is important to note that DKK1 and FRZB expression, as determined from bone marrow aspirates of the iliac crest, although very powerful, can not account for the presence of bone lesions in all patients, as cases exists that have x-ray lesions in which the multiple myeloma plasma cells do not express appreciable levels of DKK1 or FRZB. Several possibilities may account for this observation. First, it is possible that if plasma cells were isolated from MPCT at focal lesions the cells might have high levels of either these genes. Alternatively, a quantitative trait locus (QTL) for low bone mass in the general population may enhance bone lesion development even in the presence of low levels of DKK1 and FRZB. Finally, it is likely that DKK1 independent mechanisms, e.g. osteoclast hyperactivation, are also at work in the development of bone disease. Nonetheless, it is remarkable that cells from random bone marrow aspirates of the iliac crest have gene expression profiling (GEP) features expected of plasma cells derived from MPCT adjacent to lytic lesions. Thus comparative GEP studies of CT-guided fine needle aspirates of MPCT and random aspirates from the same patient should reveal stronger similarities rather than differences. Preliminary studies of this design have in fact revealed no major distinguishing GEP features, including of DKK1 and FRZB, between the two cell types.

It have recently shown that expression of the cell cycle control and DNA metabolism genes TYMS, UBE2C, CCNB1, PCNA, TK1, BUB1, BUB1B, EZH2, and TOP2A is significantly higher in MM with metaphase cytogenetic abnormalities (CA) and that these features are linked to poor survival. These same genes were also over-expressed in MM with lytic lesions and MPCT and especially in cases with both, suggesting this type of MM is also likely to have a high proliferation index and may provide a molecular explanation for why MM with >3 lytic lesions is classified as a high risk stage III disease in the Durie Salmon staging system.

Although exhibiting highly variable and sometimes very high expression in multiple myeloma plasma cells, MIP-1-alpha (CCL3/SCYA3), a chemokine implicated in OCL development and multiple myeloma bone disease, was not significantly differentially expressed in this analysis. In addition, RANKL, a known osteoclast differentiation factor with conflicting data concerning its expression on multiple myeloma plasma cells, has not been detected in any multiple myeloma plasma cells or normal bone marrow plasma cell sample tested with our microarray system.

Consistent with a key role for JUN in controlling DKK1 expression and in turn apoptosis, it has been shown that plasma cells derived from extramedullary disease, as well as primary refractory disease, and human multiple myeloma cell lines have low to undetectable levels of both JUN and DKK1. It has also been shown that primary multiple myeloma cells co-cultured with in vitro derived osteoclasts are long-lived and moderately proliferative and that these cells down-regulate JUN, FOS, FOSB, and DKK1 after co-culture (24). Thus, one of the mechanisms by which OCL may prolong multiple myeloma plasma cell survival is through the down-regulation of DKK1 via the down-regulation of JUN.

The relevance of elevated DKK1 and FRZB expression in multiple myeloma bone disease is derived from several recent studies that have shown that functional Wnt signaling is critical for osteoblast differentiation and function. Patients exhibiting loss of function mutations in the low-density lipoprotein receptor-related protein 5 (LRP5), a co-receptor for the Wnt ligand, have a condition known as osteoporosis-pseudoglioma (OPPG). Importantly, separate and distinct mutations in LRP5 result in a high bone mass (HBM) phenotype. In contrast to the OPPG mutations, the HBM defects represent gain-of-function mutations that effectively block binding of the inhibitory protein DKK1. Thus, it is speculated that high local levels of secreted DKK1 and FRZB at the sites of MPCT blocks LRP5 function on osteoblasts, which in turn results in apoptosis or a block to terminal differentiation.

Obligate carriers of the OPPG mutations can have reduced bone mass and a QTL near LRP5 on 11q12 influences bone density in the general population. It is therefore conceivable that multiple myeloma bone disease may also be influenced by this QTL, as patients inheriting a low bone mass allele and whose multiple myeloma plasma cells express high levels of DKK1 may be at higher risk of developing bone disease than those with just one of these features. The inheritance patterns of this QTL could also help explain the presence of lytic lesions in patients with low DKK1 and low FRZB. It is also interesting to speculate that the risk of conversion of monoclonal gammopathy of undetermined significance (MGUS) to multiple myeloma may also be influenced by this QTL. Thus it is of interest to determine the genotypes for this locus in a large population of multiple myeloma and MGUS cases and age-gender matched controls and correlating this with DKK1 expression, bone mass, and bone disease.

Osteolysis is the most common skeletal manifestation of neoplasia and may be focal or generalized. Given that prostate and placenta are the only adult tissues that express appreciable levels of DKK1 and that metastatic prostate adenocarcinomas to the bone are frequent and associated with osteoblastic and sometimes osteolytic lesions, it is intriguing to speculate that metastatic prostate cancers as well as other bone metastasizing tumors expressing high levels of DKK1 may also contribute to osteolytic lesions. It is also interesting to speculate that osteoporosis in the general population may also be linked to elevated DKK1.

The data linking DKK1 up-regulation after drug treatment, its down-regulation in late stage disease and after OCL co-culture, its high expression in multiple myeloma with bone lesions, and published reports on the molecular biology of DKK1 expression has prompted the inventors to develop a working model for DKK1 in multiple myeloma. It is envisioned that in the early stages of disease, an inherent genomic instability induces expression of DKK1 which in turn induces apoptosis of multiple myeloma cells and may explain the relatively slow progression of the disease, as cell growth is tempered by a high rate of DKK1 induced apoptosis. However, as the disease progresses, high levels of DKK1 secreted from the multiple myeloma cells results in profound defects in osteoblast function and combined with osteoclast hyper-activation leads to uncoupled bone turnover and the development lytic bone lesions and diffuse osteopenia. As osteoclast numbers increase these cells induce the down-regulation of JUN and DKK1 in multiple myeloma plasma cells, liberating the multiple myeloma plasma cells from the pro-apoptotic effects of DKK1, resulting in an increased tumor cell burden. Although DKK1 loss in the early stages of disease progression is likely due to down-regulation of JUN that is induced by an osteoclast derived factor, permanent loss of DKK1 expression late in disease is likely due to the loss of p53. Thus, DKK1 in multiple myeloma has a paradoxical twist, in that even though secreted DKK1 may facilitate apoptosis of multiple myeloma plasma cells, it may also block osteoblast growth and differentiation, which in turn creates a bone marrow microenvironment primed for disease progression. If true, utilization of this knowledge could lead to the development of new therapies for MM that accentuate and preserve the pro-apoptotic effects of DKK1 on MM PC, but at the same time prevent its bone damaging effects.

EXAMPLE 21 DKK1 Is Secreted by Plasma Cells and Contributes to Osteolytic Lesions in Multiple Myeloma

Examples 20-22 show that DKK1 is the only gene coding for secreted proteins that is significantly elevated in the malignant plasma cells from patients with bone lesions at diagnosis. DKK1 protein is synthesized and secreted into the marrow space where elevated levels also correlate with plasma cell gene expression levels and the presence of bone lesions. Finally, it is shown that plasma from multiple myeloma bone marrow containing high levels of DKK1 blocks in vitro osteoblast differentiation in a DKK1-dependent manner, whereas plasma from normal healthy donors does not.

Because osteolytic lesions develop at the site of MRI-defined focal medullary plasmacytomas and DKK1 levels strongly correlate with the presence of MRI-focal lesions, it is speculated that DKK1 protein levels are high in the environment surrounding “nests” of plasma cells, leading to an incapacitation of osteoblasts adjacent to these plasma cell clusters. Concentration gradients of the Wnt ligands and their soluble inhibitors, e.g. DKK1, are important in the creation of body segmentation and cellular polarity. Thus, DKK1 may exert most of its inhibitory effects directly adjacent to plasmacytomas, as thus may provide a functional explanation as to why lytic lesions are always found next to medullary plasmacytomas and not in unaffected areas. Because plasma cells make up ≦5% of all bone marrow cells and plasma cells are the only source of DKK1 in human bone marrow, elevated DKK1 levels in the marrow could also be related to systemic osteoblast defects and osteopenia when tumor cell burden reaches a critical threshold. Published work showed that when tumor cell burden increases above 50%, osteoblast mineral apposition rates are dramatically reduced.

Not all multiple myeloma patients with bone lesions exhibited elevated levels of DKK1. Several possibilities may account for this observation. Obligate carriers of the OPPG mutations can have reduced bone mass and a quantitative trait loci (QTL) near LRP5 on 11q12 influences bone density in the general population. Thus, QTL inheritance patterns could explain the presence of lytic lesions in patients with low DKK1 expression, as the presence of a low bone mass allele and low DKK1 levels may create a high risk for developing bone lesions. It is also possible that the Wnt signaling antagonist FRZB, which is elevated in multiple myeloma and multiple myeloma with osteolytic lesions (data not shown), and which negatively regulates chondrocyte development could synergize with DKK1 to contribute to osteoblast dysfunction and bone lesions.

Although Wnt/b-catenin signaling defects are implicated in hereditary syndromes affecting bone, the data presented herein are the first evidence that disrupting this signaling cascade is also linked to bone destruction in non-hereditary conditions. These data also support the notion that elevated DKK1, and possibly other Wnt signaling antagonists, might play a role in other forms of bone loss. Soluble Wnt antagonist SFRP-2, and possibly DKK1, is downregulated by estrogen; thus it is important to determine whether DKK I protein levels or other Wnt antagonists are elevated in post-menopausal women and whether protein levels correlate with osteoporosis. Furthermore, given that breast cancer metastasis to the bone is frequently associated with osteolytic lesions, it is important to determine if DKK1 expression is elevated in these cases. Finally, these data support the concept that pharmacological antagonism of DKK1 action may be a means of controlling both malignancy-related bone loss, and post-menopausal or other forms of osteoporosis.

Global Gene Expression Profiling of Malignant Plasma Cells Links DKK1 with Bone Lesions

One hundred seventy four patients with newly diagnosed multiple myeloma, 45 normal healthy donors, and 10 patients with Waldenström's macroglobulinemia were studied in this example. The characteristics of the multiple myeloma patients are presented in Table 25.

Bone images were reviewed on a CANON PACS (Picture Archiving and Cataloging System). MRI scans were performed on 1.5 Tesla GE SIGNA scanners. X-rays were digitized from film in accordance with American College of Radiology (ACR) standards. MRI scans and x-rays were linked to the CANON PACS system using the ACR's DICOM (Digital Imaging and Communications in Medicine) standard. Imaging was done in accordance with manufacturers' specifications. MRI images were created with pre- and post-gadolinium T1-weighting and STIR (short-tau inversion recovery) weighting.

MRI-defined focal lesions can be observed before the development of radiologically identifiable lytic lesions; therefore, T1-weighted and STIR-weighted imaging was used to evaluate bone lesions in multiple myeloma. Bone disease in multiple myeloma patients was modeled using logistic regression. DKK1 protein and gene expression values, measured using the signal calls from the Version 5.01 AFFYMETRIX Microarray Analysis Suite, were transformed using the Log Base 2 function prior to entry into the logistic regression model. Candidate genes were reduced to 58 genes with the lowest p-value from logistic regression (p<0.00012). T-tests with permutation-adjusted p-values verified the significance of the 58 genes at the 0.05 level. Except in the process of reducing candidate genes, p-values less than 0.05 were considered significant and p-values less than 0.10 were considered marginally significant. Expression intensities of genes identified by logistic regression were visualized with ClusterView (25). Gene expression and protein levels were correlated with Spearman or Pearsons correlation metric.

Logistic regression and permutation analysis of global gene expression differences in purified plasma cells from patients with none (n=36) and those with 1 or more (1+) (n=137) MRI-defined focal lesions identified 30 downregulated and 28 upregulated genes that were significantly differentially expressed (p<0.0001) in patients with 1+ MRI lesions (FIG. 23A). The soluble Wnt/b-catenin signaling antagonist DKK1 ranked 4th in significance (p=4.3×10⁻⁶) and represented the only gene coding for a secreted factor in the list. DKK1 was undetectable by microarray analysis of bone marrow plasma cells from 45 normal healthy donors and 10 patients with Waldenström's macroglobulinemia, a plasma cell malignancy that lacks lytic bone disease (data not shown).

Using the same comparative ranking criteria for x-ray identifiable osteolytic lesions, DKK1 expression was again significantly elevated in patients with 1+ lesions (p=0.0068), but ranked 199 of ˜10,000 genes investigated (data not shown). Because osteolytic lesions always develop at sites of MRI-detectable focal lesions and MRI lesions can be present in the absence of lytic lesions, it is hypothesized that multiple myeloma patients with no x-ray lesions, but high DKK1 expression, would have MRI lesions, thus explaining the reduced ranking of DKK1. Indeed, removing patients with 1+ MRI lesions from the group with no x-ray lesions resulted in DKK1 moving to the 5th most significant gene (p=0.0000089) when comparing those patients with no x-ray lesions and no MRI lesions with patients who had 1+ x-ray lesions (data not shown).

Increased Log2 (DKK1) expression increases the likelihood of having 1+ MRI lesions (OR 1.42 [95% CI: 1.21, 1.66], p<0.0001) (FIG. 23B). This relationship is still statistically significant, but of less magnitude for patients with 1+ x-ray lesions (OR: 1.19 [95% CI: 1.04, 1.35], p=0.0084). Again, removing patients with 1+ MRI lesions from the no x-ray lesion group reveals that the relationship of DKK1 and lesions detected by x-ray (adjusted) (OR 1.43 [95% CI: 1.20, 1.69], p<0.0001) mirrors that of lesions detected by MRI. Though this is not conclusive evidence of a link between elevated DKK1 and bone lesions, the pattern of DKK1 expression is consistent with the theory that DKK1 and MRI are strong early indicators of x-ray-defined osteolytic lesions.

Immunohistochemistry and Immunofluorescence

A polyclonal goat anti-human DKK1 antibody (R&D Systems, Minneapolis, Minn.) diluted 1:200 in TBS was incubated on formalin-fixed, paraffin-embedded multiple myeloma bone marrow biopsy sections for 2 hours at room temperature. Anti-kappa or -lambda antibodies (Dako, Carpenteria, Calif.) diluted 1:1200 were incubated on adjacent sections for 30 minutes at room temperature. Antigen-antibody reactions were developed with DAB (using biotinylated anti-goat antibody (1:400 dilution, Vector Laboratories, Burlingame, Calif.) and streptavidin-horse radish peroxidase (Dako)), and counterstained with Hematoxylin-2. For immunofluorescence, cells were fixed in 4% paraformaldehyde, blocked with 1% bovine serum albumin (BSA)/Hank's balanced salt solution (HBSS) for 10 minutes, then incubated with 1 ug/ml anti-human DKK1 antibody followed by a Rhodamine-conjugated rabbit anti-goat IgG F(ab′)2 fragment (1:500 dilution, Jackson ImmunoResearch, West Grove, Pa.). Cytoplasmic immunoglobulin kappa or lambda light chains were stained with FITC-conjugated goat anti-human kappa or lambda IgG at 1:100 dilution (Vector Laboratories). All slides were examined with fluorescence optics on an OLYMPUS BX60 epifluorescence microscope and photographed at 1000× magnification.

DKK1 protein is synthesized by malignant and normal plasma cells. Serial sections from bone marrow biopsies of 30 multiple myeloma cases stained with antibodies against cytoplasmic immunoglobulin kappa or lambda light chain (cIg) and DKK1 revealed plasma cells expressed DKK1 in a manner consistent with gene expression data (FIGS. 24A-24D). Simultaneous two-color immunofluoresence microscopy on mononuclear cells from bone marrow aspirates of 30 multiple myeloma patients and 9 normal healthy donors was consistent with immunohistochemistry results, showing DKK1 protein expression exclusively in cIg-restricted plasma cells (FIGS. 24E-24H). As seen in the multiple myeloma bone marrow aspirates, non-plasma cells in normal marrow did not express DKK1; however, approximately ⅓ to ½ of cIg-positive plasma cells expressed DKK1. Although DKK1 expression was not detected by microarray, DKK1 expression, albeit low, could be detected in purified bone marrow plasma cells by real time RT-PCR (data not shown).

TABLE 25 Myeloma Patient Characteristics and Their Relationship to MRI Lesions Variable n/N % MRI = 1+ MRI = 0 p value Age ≧65 yr 23/169 14 17/132 (12.9%) 6/36 (16.7%) 0.5869* Caucasian 147/169  87 113/132 (85.6%) 33/36 (91.7%) 0.4163* Female 68/169 40 55/132 (41.7%) 13/36 (36.1%) 0.5472 Kappa light chain 104/165  63 79/128 (61.7%) 24/36 (66.7%) 0.5874 Lambda light chain 61/165 37 49/128 (38.3%) 12/36 (33.3%) 0.5874 IgA subtype 39/169 23 25/132 (18.9%) 14/36 (38.9%) 0.0120 B2M ≧4 mg/L 60/169 36 47/132 (35.6%) 13/36 (36.1%) 0.9553 CRP ≧4 mg/L 12/166 7 11/129 (8.5%) 1/36 (2.8%) 0.4662* Creatinine ≧2 mg/dL 19/169 11 16/132 (12.1%) 3/36 (8.3%) 0.7673* LDH ≧190 UI/L 52/169 31 44/132 (33.3%) 8/36 (22.2%) 0.2012 Albumin <3.5 g/dL 23/169 14 19/132 (14.4%) 4/36 (11.1%) 0.7868* Hgb <10 g/dL 40/169 24 31/132 (23.5%) 8/36 (22.2%) 0.8736 PCLI ≧1% 23/150 15 18/119 (15.1%) 4/30 (13.3%) 1.0000* ASPC ≧33% 109/166  66 82/129 (63.6%) 26/36 (72.2%) 0.3342 BMPC ≧33% 104/166  63 79/129 (61.2%) 24/36 (66.7%) 0.5522 Cytogenetic 52/156 33 45/121 (37.2%) 6/34 (17.6%) 0.0321 abnormalities CA13 or hypodiploid 33/52  63 31/121 (25.6%) 3/34 (8.8%) 0.0365 Other CA 19/52  37 53/103 (51.5%) 16/32 (50.0%) 0.8855 FISH13 69/136 51 103/136 (75.7%) 28/36 (77.8%) 0.7981 Osteopenia 131/173  76 1+ Lesions by MRI 137/173  79 3+ Lesions by MRI 108/173  62 1+ Lesions by X-ray 105/174  60 3+ Lesions by X-ray 69/174 40 *Fisher's Exact test, otherwise Chi-square test

EXAMPLE 22 Correlation Between Levels of DKK1 Protein in Bone Marrow Plasma and the Presence of Bone Lesions

An enzyme-linked immunosorbent assay (ELISA) was used to measure DKK1 protein concentration in the bone marrow plasma. NUNC IMMUNO MaxiSorp surface microtiter plates were coated with 50 ul of anti-DKK1 antibody at 1 ug/ml in 1× PBS, pH 7.2 at 4° C. overnight, and blocked with 4% BSA. Bone marrow plasma from multiple myeloma, Waldenström's, and normal donors was diluted 1:50 in dilution buffer (1× PBS+0.1 Tween-20+1% BSA). A total of 50 μl was loaded per well and incubated overnight at 4° C., washed and incubated with biotinylated goat anti-human DKK1 IgG (R&D Systems) diluted to 0.2 ug/ml in dilution buffer, followed by addition of 50 μl of 1:10,000 dilution of streptavidin-horse radish peroxidase (Vector Laboratories) all according to manufacturer's recommendations. Color development was achieved with the OPD substrate system (Dako) based on manufacturer's instructions. Serial dilutions of recombinant human DKK1 (R&D Systems) were used to establish a standard curve. The cell line T293, which does not express endogenous DKK1 and T293 with stably transfected DKK1 were used to validate the ELISA assay.

DKK1 protein concentration in the bone marrow plasma from 14 normal healthy donors was 8.9 (S.D. 4.2) ng/ml. In contrast, the mean plasma concentration in 205 newly diagnosed multiple myeloma patients was 28.37 (S.D. 54.45) ng/ml and the mean level in 9 Waldenström's acroglobulinemia patients was 5.5 (S.D. 2.4) ng/ml. Both DKK1 gene expression and DKK1 protein levels determined in 107 multiple myeloma cases were strongly correlated (r=0.65, p<0.00001) (FIG. 25A). DKK1 protein levels were correlated with bone lesions in 74 multiple myeloma in which both measurements were available. DKK1 protein levels were significantly higher in patients with 1+ MRI versus those with no MRI lesions (OR: 1.98 [95% CI: 1.18, 3.32], p=0.012) (FIG. 25B), but only marginally significant for 1+ x-ray lesions versus no lesions (OR: 1.38 [95% CI: 0.95, 2.00], p=0.09) (FIG. 25B). However, as observed for DKK1 gene expression (see FIG. 23B), serum DKK1 protein levels can discriminate patients with no MRI and no x-ray lesions from patients with 1+ MRI and no x-ray lesions (OR: 7.46 [95% CI: 1.40, 39.82], p=0.0186), but cannot discriminate the 1+ MRI lesions and 1+ x-ray lesions group from the 1+ MRI lesions/no x-ray lesions group (OR: 1.14 [95% CI: 0.98, 1.32], p=0.5752) (FIG. 25B). These data show that DKK1 proteins levels are elevated in MM bone marrow, that DKK1 gene expression levels in multiple myeloma plasma cells correlate with DKK1 protein levels in the serum, and that DKK1 serum levels also correlate with the presence of bone lesions.

EXAMPLE 23

Multiple Myeloma Marrow Serum Blocks in vitro Osteoblast Differentiation in a DKK1-Dependent Fashion

BMP-2 specifically converts the differentiation pathway of C2C12 myoblasts into that of osteoblast lineage and BMP-2 induced osteoblast differentiation of mesenchymal precursor cells in vitro involves Wnt/b-catenin signaling. Thus, it is of interest to determine if multiple myeloma serum containing high levels of DKK1 could block BMP-2 induced alkaline phosphatase (ALP) production by C2C12 cells.

C2C12 mesenchymal precursor cells (American Type Tissue Culture, Reston, Va.) were cultured in DMEM (Invitrogen, Carlsbad, Calif.) supplemented with 10% heat-inactivated fetal calf serum. BMP-2 induced alkaline phosphatase activity in C2C12 cells was measured as previously described (26-27). Briefly, C2C12 cells were plated at 2×10⁴/cm² in 5% FCS and treated 24 hours later by addition of 0.1 ug/ml BMP-2+10% normal serum, or 10% multiple myeloma patient serum (resulting in final DKK1 concentration of at least 15 ng/ml), or 10% multiple myeloma patient serum+anti-DKK1 antibody or non-specific goat polyclonal IgG (Jackson ImmunoResearch) at a 5:1 molar ratio to DKK1. After 5 days, ALP activity was determined in cell lysates using an Alkaline Phosphatase Opt Kit (Roche Molecular Biochemicals). Cell lysates were analyzed for protein content using the micro-BCA assay kit (Pierce, Rockford, Ill.). Each experiment was done in triplicate.

It was first showed that TGF-b (2.5 ng/ml) and recombinant human DKK1 (12.5 ng/ml) could block ALP production after treatment with 0.1 ug/ml of BMP-2 for 5 days (data not shown). ALP levels were undetectable in C2C12 cells grown in 5% FCS for 5 days (FIG. 26). C2C12 cells treated with BMP-2 and 10% serum from a normal donor induced ALP activity to a mean of 0.72 mM/min/mg total protein. Cells treated with 10% serum from two multiple myeloma cases (final DKK1 concentration 20 ng/ml and 16.8 ng/ml) resulted in a significant reduction of ALP levels relative to the normal control. However, co-incubation with DKK1 antibodies resulted in a significant increase in ALP levels. Co-incubation with a non-specific polyclonal goat IgG did not have a significant affect on ALP levels relative to multiple myeloma serum alone. These data show that serum from multiple myeloma patients, but not normal donors, can block in vitro osteoblast differentiation in a DKK1-dependent fashion.

EXAMPLE 24 Gene Expression Profiling Implicates Wnt Signaling in Multiple Myeloma

In addition to a possible role for FRZB and DKK1 in multiple myeloma (MM) bone disease and DKK1 in drug induced MM cell apoptosis, additional components of the Wnt signaling system also show expression perturbations in MM. Wnt signaling is mediated by the Frizzled (FZD1-FZD10) seven-transmembrane-span receptors alone or when complexed with heterotrimeric G proteins or essential co-receptors LRP5/6. Intracellular signaling branches into either the canonical b-catenin-TCF pathway that activates target genes in the nucleus, the Wnt/Ca²⁺ pathway or the planar cell polarity pathway which involves jun N-terminal kinase (JNK) and cytoskeleton modifications. With respect to the canonical b-catenin-TCF pathway, the absence of Wnt signal, which can be blocked by antagonist like FRZB and DKK1, results in b-catenin being sequestered in a complex with Axin, adenomatous polyposis coli (APC), CKIa and/or CKIe, and GSK-3b. Both CKIa/e and GSK-3b phosphorylate b-catenin thereby targeting the protein for ubiquination and degradation by the proteasome. In the presence of Wnts, disheveled (Dsh) blocks b-catenin degradation possibly by recruiting GBP/Frat1, which displaces GSK3b from axin resulting in b-catenin stabilization. Stabilized b-catenin migrates to the nucleus where it associates with TCF/LEF transcription factors.

Using the AFFYMETRIX HuGenFL microarray, it has previously been shown that, with respect to normal bone marrow PC, the TCF7 (TCF1) transcription factor and APC are down-regulated and up-regulated in MM, respectively (1). A recent analysis of 60 genes involved in or activated by WNT signaling in 222 MM and 45 normal bone marrow PC using the second-generation U95Av2 microarray revealed that TCF7 expression remained significant and represented the most significantly down-regulated WNT signaling gene in MM. The APC significance was lost in this new analysis probably owing to a change in the probe set interrogating the gene. The Wnt receptor FZD2 with a mean expression level of 1034 in MM and 2657 in normal bone marrow PC, represented the second most significant down-regulated gene. Importantly, FZD2 has also been found to be significantly down-regulated in MGUS and represents the only WNT signaling component found deregulated in benign plasma cell dyscrasia. DKK1 and FRZB, with ratios (MM/normal bone marrow PC) of mean expression levels of 25 and 14 respectively, represented by far the most significantly up-regulated WNT components in this analysis.

WNT5A and WNT10B tended to show up-regulation and down-regulation in MM respectively (1). In the new analysis the mean expression level for WNT5A was 217 (range 29 to 484) whereas the mean expression level in MM was 1299 (range 16 to 10782). In contrast, the mean expression level of WNT10B in normal bone marrow PC was 3239 (range 1552 to 6105) and 1881 (range 481 to 15354) in MM. Thus, these two ligands show inverse relationships with respect to normal bone marrow PC. Furthermore, the two genes also tend to be inversely correlated within the patient population.

Recent studies have shown that rat Wnt5a is a ligand for Rfz2 (FZD2) and that binding of the ligand to receptor signals through phosphodiesterase and cyclic GMP (28). Correlation analysis of the expression of FZD2 and WNT5A in PC from 222 newly diagnosed patients has shown that PC with low FZD2 tend to have high expression of WNT5A and those with high FZD2 to have low WNT5A levels. One possible explanation for this phenomenon is that normal PC utilizes the FZD2 signaling pathway and that down-regulation of FZD2, an apparent early event in MM, results in a compensatory up-regulation of WNT5A.

Yamanaka et al. have recently shown that Wnt5a is also capable of activating JNK in cultured cells, and that the JNK pathway mediates the action of Wnt5a to regulate convergent extension movements, a vertebrate correlate of the planar cell polarity pathway of Drosophila (29). Lisovsky and colleagues have also shown that Xenopus Frizzled 8 (Xfz8) activates JNK and triggers rapid apoptotic cell death in gastrulating Xenopus embryos (30). They showed that the apoptotic signaling was shared by a specific subset of Frizzled receptors, was inhibited by Wnt5a, and occurred in a Dishevelled- and T cell factor (TCF)-independent manner (30). These data suggests that WNT5A over-expression in MM may prevent apoptosis through inhibition of JNK signaling. Hideshima et al. have demonstrated that the proteasome inhibitor PS-341 activates JNK, that this activation is correlated with MM cell apoptosis, and that blocking JNK activation abrogates PS-341-induced cell death (31). Thus it will be interesting to determine if MM cells cultured in the presence of excess WNT5A demonstrate resistance to PS-341-induced apoptosis.

Previous studies on the effects of Wnts in hematopoiesis suggests that alteration in the ratio of specific Wnt ligands, especially Wnt5A and Wnt10B, may have profound effects on normal bone marrow stem cell function (32). Brandon and colleagues have recently shown that treatment of hematopoietic progenitor cell-enriched bone marrow cultures with soluble WNT11 or WNT5a inhibited macrophage formation and enhanced monocyte and RBC production (33). Thus, one of the consequences of elevated WNT5A in MM may be to drive progenitor cells to monocytes at the expense of macrophage development. This increased pool of monocytes, in the presence of osteoclast differentiation factors such as RANKL, could theoretically contribute to increased osteoclast numbers.

Van Den Berg and colleagues have demonstrated that Wnt-5A, Wnt-2B, and Wnt-10B are expressed in fetal bone stromal cells, that these genes are expressed to varying levels in hematopoietic cell lines derived from T cells, B cells, myeloid cells, and erythroid cells, but that only Wnt-5A is expressed in CD34(+)Lin-primitive progenitor cells (33). The authors also showed that the number of hematopoietic progenitor cells is markedly affected by exposure to stromal cell layers expressing Wnt genes. Colony formation by cells expanded on the Wnt-expressing co-cultures was similar for each of the three genes, indicating similar action on primitive progenitor cells; however, Wnt-10B showed differential activity on erythroid progenitors (BFU-E) compared with Wnt-5A and Wnt-2B (33). Co-cultures containing Wnt-10B alone or in combination with all three Wnt genes had threefold to fourfold lower BFU-E colony numbers than the Wnt-5A- or Wnt-2B-expressing co-cultures (33). The relationship of Wnt signaling and stromal cell-hematopoietic cell development has been furthered by studies showing that conditioned medium containing Wnt-3a dramatically reduced the production of B lymphocyte and myeloid lineages, except for macrophages, in long-term bone marrow cultures grown on stromal cells (34). In contrast, the same conditioned medium did not affect the generation of these cells in stromal cell-free conditions. The authors took these results to suggest that Wnt proteins exert their effects through stromal cells and supported this hypothesis by showing that the same effects could be mimicked by the expression of a stabilized form of beta-catenin in stromal cells (35).

Evidence for a direct role of Wnt signaling in B-cell biology and B-cell disease is derived from recent studies showing that Wnt signaling requires BCL9-mediated recruitment of pygopus to the nuclear b-catenin-TCF complex (36). GEP data from 222 newly diagnosed MM and 45 normal bone marrow PC has revealed elevated expression of BCL9 in approximately one-third of MM (mean 2128; range 758 to 4735) when compared to normal PC (mean 1447; range 394 to 2305). Reya et al. have shown that mice deficient for lymphocyte enhancer factor-1 (LEF-1) exhibit defects in pro-B cell proliferation and survival in vitro and in vivo, that Lef1^(−/−) pro-B cells display elevated levels of fas and c-myc transcription, and that Wnt proteins are mitogenic for pro-B cells and that this effect is mediated by Lef1 (37).

A role for WNT signaling in normal PC development is indicated by several observations. First, global GEP of human plasma cell differentiation revealed that whereas WNT10B is not expressed in tonsil BC, it is turned on in both tonsil and bone marrow PC (3). In contrast, FRZB was significantly down-regulated in the transition of immature tonsil PC to mature bone marrow PC (3). Secondly, Alexander et al. have demonstrated that syndecan-1 (CD138/SDC1), a transmembrane heparan sulfate proteoglycan expressed exclusively on mature plasma cells within the hematopoietic lineage, is required for Wnt-1-induced mammary tumorigenesis in mice (38), suggests that one possible function for syndecan-1 in PC biology is to facilitate WNT signaling. Finally, a recent gene expression study of mouse plasma cell differentiation has shown that Axin and Frat1 are down-regulated in PC with respect to BC, whereas b catenin and disheveled were equally expressed in both cell types (39).

EXAMPLE 25 Gene Expression Profiling Before and After Short-Term Drug Treatment to Identify Potential Mechanisms of Action

All current chemotherapy regimens for multiple myeloma (MM) treatment attempt to use combinations of multiple drugs affecting non-overlapping, and non-cross resistant pathways. It is impossible to define, in the context of these extensive combinations, the molecular mechanisms of action of individual components. Short-term serial gene expression studies of tumor cells after single agent drug treatment may provide insight into the mechanisms of action, especially when combined with clinical response data. This knowledge, if confirmed, can lead to the development of second-generation drugs with more effective response profiles and less toxicities. In addition, knowledge of pathways will allow development of drugs that target discrete points along pathways allowing use of complementary or synergistic drugs. Potential advantages of performing in vivo studies are that drug metabolism, tumor cell host interactions, and drug response correlations can be considered.

In an effort to gain insight into the mechanism of action of various single-agent compounds, the inventors have performed baseline and 48-hour follow-up gene expression profiling (GEP) on patients before and after therapy with dexamethasone (n=20), thalidomide (n=18), the thalidomide derivative IMID (n=15), or the proteasome inhibitor PS-341 (n=11) (40).

Based on the t-test for differences in quantitative expression changes, dexamethasone induced the greatest change (147 genes p<0.0001; 51 up and 96 down). PECAM1 was down-regulated in 20 of 20 cases and represented the most significantly altered gene (p=5.8×10−9) after dexamethasone treatment. PECAM1 is an adhesion molecule that is up-regulated as PC mature from the tonsil to bone marrow stage of development (3), suggesting a critical role for this protein in PC adhesion to the bone marrow stroma. Thus, it is possible that down-regulation of PECAM1 may result in MM PC detachment and an increased rate of spontaneous or chemotherapy induced apoptosis.

Virtually all (18 of 20) cases treated with dexamethasone also showed down-regulation of the pro-angiogenic molecule VEGF and the anti-apoptotic molecule MCL1, both of which have been implicated in MM biology. Since VEGF is up-regulated upon adherence of MM cells to stroma, it is not clear whether VEGF down-regulation is directly caused by dexamethasone or is a reflection of the down-regulation of PECAM1 and detachment of the cells from stroma. Given that most patients initially respond to dexamethasone treatment, but eventually develop resistance, performing GEP on patients after treatment with dexamethasone that are known to be resistant to the drug might provide insight into the mechanisms of action. For example, it may be found that dexamethasone resistant MM PC may not down-regulate PECAM1 and VEGF after short-term treatment.

Surprisingly, using the same t-test analysis, PS-341 only induced significant changes in 9 genes (p<0.001; 2 up and 7 down). The down-regulation of the Cockayne syndrome 1 gene (CKN1) represented the most significant change (p=6×10−6) after PS-341 treatment. CKN1 encodes a WD repeat protein that interacts with CSB protein and a subunit of RNA polymerase II TFIIH and mutations of CKN1 are associated defective strand-specific repair of transcriptionally active genes. Thus, the down-regulation of CKN1 by PS-341 may have negative effects on RNA polymerase II transcription and may explain the low number of altered genes relative to dexamethasone, thalidomide, and IMID. A possible mechanism of action of the drug may be to impair DNA damage repair through the down-regulation of CKN1. In such a scenario inactivation of CKN1 could result in cells with germ line TP53 being driven into an apoptotic program rather than a DNA repair pathway. Such a scenario, if true, suggests that combining PS-341 with alkylating agents may have synergistic effects.

IMID or CC-5013, a potent thalidomide analog, induced changes in 98 genes (p<0.001; 41 up and 57 down), whereas thalidomide induced significant changes in 57 genes (p<0.001; 29 up and 28 down). Given that IMID and thalidomide are related molecules, it is speculated that consistent and common changes in gene expression influenced by both drugs might point to mechanisms of action. Seven genes, CROT, IL6, TPBG, ALB, PLSCR1 and, DKK1 were activated by both drugs with up-regulation after IMID treatment being more pronounced for all genes, attesting to the higher potency of the derivative. Importantly, Dickkopf1 (DKK1), a secreted antagonist of Wnt signaling, was hyperactivated a median of 125% in 14 of 18 patients treated with thalidomide and up-regulated a median of 315% in 13 of 15 cases treated with IMID. Virtually all MM cases not showing a hyperactivation of DKK1 after treatment with both drugs had little or no detectable expression in the baseline sample, suggesting that these cases had an inherent inability to activate DKK1 expression. Along these lines it was also noted that whereas DKK1 was expressed in nearly 80% of newly diagnosed MM, virtually all cases of PC leukemia and plural effusions from end stage MM lack expression of DKK1. Given that DKK1 is a direct target of p53 and p53 loss is frequently seen in late stage MM, it is possible that the lack of expression and/or inability to activate DKK1 in MM may be due to loss of p53. In fact, one of the cases of newly diagnosed MM that showed no DKK1 at baseline or after 48 hr treatment with thalidomide was primary refractory to all interventions. The p53 status in this patient was not known.

Of 648 genes exhibiting a greater than 50% (range 51% to 408%) change in median expression level after IMiD treatment, DKK1, at 315% increase ranked as the 4^(th) most significantly altered gene. In a similar analysis after thalidomide treatment, DKK1 was ranked 13^(th) out of 217 genes. Conversely, although hyperactivated in 14 of 20 patients, DKK1 only showed a median increase of 23%, was ranked 1426^(th) and not represented in the list of 280 genes exhibiting an up-regulation of at least 50% (range 51% to 470%) by dexamethasone. The effects of PS-341 were even more skewed from the IMID and thalidomide data in that only 7 of 15 patient samples exhibited increases in DKK1 and the median change was essentially undetectable at −1.60%. DKK1 ranked 7,532 of 12,000 genes tested. Thus, these data provide the first evidence that for the in vivo effects of drug treatment on DKK1 expression, thalidomide and IMID have powerful up-regulating effects; dexamethasone has an intermediate effect; and the proteasome inhibitor PS-341 has little or no effect.

It is important to determine if the drug has a direct activating effect or whether the increase really reflects the rapid and preferential killing of cells not expressing DKK1 which would in turn create a virtual up-regulation. Several points argue against the latter possibility. First, DNA damaging agents like UV irradiation, H₂O₂, cisplatin, and BCNU activate DKK1 in vitro and this activation sensitizes cells to apoptosis. Second, it is unlikely that a massive cell kill occurred within 48 hours after in vivo administration. Finally, the inventors have recently found that in vitro treatment of the human MM cell line ARP1 with thalidomide, IMID, and dexamethasone results in the activation of DKK1.

Given the fact that in vitro DNA damage triggers DKK1 expression, it is speculated that DNA instability present in MM PC may be a trigger of DKK1 activation in newly diagnosed, previously untreated cases of MM. Thus, DKK1 not only could be a major mediator of MM PC cell death after drug treatment, but also a mediator of apoptosis in these cells as a result of endogenous DNA damage. Indirect support for a role for DKK1 in MM cell apoptosis comes from previous studies showing that 1) DKK1 is activated by BMP-4, and 2) that treatment of MM cell lines and primary MM samples with BMP-4 can inhibit proliferation and induce apoptosis. These data suggests that one possible mechanism of BMP-4 induced MM PC killing is through the activation of DKK1.

DKK1 has been shown to be critical for limb morphogenesis during vertebrate embryogenesis. DKK1 null mutant embryos show duplications and fusions of limb digits whereas forced over expression of DKK1 in embryonic limb buds inhibits limb outgrowth. The limb defects resulting from over expression of DKK1 have a strong resemblance to the limb defects seen in thalidomide embryopathy. Thus, an intriguing implication of the link between thalidomide and DKK1 activation is that disruption of WNT signaling through DKK1 activation by thalidomide may be the long sought mechanism by which thalidomide causes such limb malformations. Interestingly, a link between DKK1 expression and MM-specific bone defects has become apparent through the use of microarray profiling (see above).

Thus, in vivo monitoring of gene expression changes following single agent drug treatment appears to be a feasible approach to study the effect of treatment and molecular mechanisms of action. These types of study have powerful advantages over in vitro studies of the same design, in that response, tumor cell host interactions, and non-tumor cell effects (variables that cannot be faithfully recapitulated in model systems) can be taken into account.

The following references are cited herein:

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Any patents or publications mentioned in this specification are indicative of the levels of those skilled in the art to which the invention pertains. Further, these patents and publications are incorporated by reference herein to the same extent as if each individual publication was specifically and individually indicated to be incorporated by reference. 

1. A method for identifying genes diagnostic of a multiple myeloma in an individual, comprising the steps of: isolating plasma cells from individuals with or without multiple myeloma; obtaining expression profiles of genes comprising the plasma cells isolated from the individuals; and identifying, via statistical analysis, genes with levels of expression in multiple myeloma patients significantly different from corresponding levels in individuals without multiple myeloma, wherein the genes with a differential expression level are diagnostic of the multiple myeloma in the individual.
 2. The method of claim 1, wherein the differentially expressed genes are potential therapeutic targets for multiple myeloma.
 3. The method of claim 1, wherein the differentially expressed genes are listed in Table 4, Table 5 and Table
 8. 4. The method of claim 1, wherein the differentially expressed genes are GART, APOC1, BCL7B, PRKAR2B, HNMT, ABL1, NEK2, MLLT3, CCN5L2, NAP1L4, KIAA00, GLDC, COX17, USP4, P5-1, S100A9, CAPN1, COX6B, C-KIT, MIC2, MSX1, LIF3, PHB, and DNMT1 and comprise a model to diagnose a subgroup of multiple myeloma.
 5. The method of claim 1, wherein the differentially expressed genes are GMPS, CD24, QSCN6, PTPRK, PYGL, PF4V1, ILF3, PLA2G7, MTA1, ABL1, ITGB2, MVP, CD163, and H2B and comprise a model to discriminate among normal, hyperplastic and malignant plasma cells.
 6. The method of claim 1, further comprising the step of: administering a pharmacological dose of a therapeutic drug or agent effective to alter differential expression of the multiple myeloma genes or to target a biochemical pathway associated with a product of the multiple myeloma genes.
 7. The method of claim 6, wherein altering differential gene expression comprises increasing expression of one or more genes in Table 4 or inhibiting expression of one or more of genes in Table 5 and Table 9 or a combination thereof.
 8. A method for diagnosing a subgroup of multiple myeloma in an individual, comprising the steps of: isolating plasma cells from an individual; and obtaining mRNA expression levels of a group of 24 genes GART, APOC1, BCL7B, PRKAR2B, HNMT, ABL1, NEK2, MLLT3, CCN5L2, NAP1L4, KIAA00, GLDC, COX17, USP4, P5-1, S100A9, CAPN1, COX6B, C-KIT, MIC2, MSX1, LIF3, PHB, and DNMT1 in the plasma cells; and performing statistical analysis on the expression levels of the genes to compute a statistically significant value based on differential expression of the group of genes, wherein the computed value correlates to a diagnosis for a subgroup of multiple myeloma.
 9. The method of claim 8, wherein the subgroups of multiple myeloma are MM1, MM2, MM3, and MM4.
 10. A method of discriminating normal, hyperplastic and malignant plasma cells in an individual, comprising the steps of: obtaining mRNA expression patterns of a group of fourteen genes GMPS, CD24, QSCN6, PTPRK, PYGL, PF4V1, ILF3, PLA2G7, MTA1, ABL1, ITGB2, MVP, CD163, and H2B in a sample of plasma cells from the individual; performing a discriminant analysis on the gene expression patterns to compute a discriminant score; and comparing the discriminant score to a predictive cutoff value statistically determined from a control model of the fourteen genes; wherein a score below the cutoff value is indicative that the plasma cells in the sample are normal and a score above the cutoff is indicative that the plasma cells are hyperplastic or malignant.
 11. A method of developmental stage-based classification for multiple myeloma, comprising the steps of: (a) isolating plasma cells and B cells from normal individuals; (b) isolating nucleic acid samples from the plasma cells and B cells; (c) hybridizing the nucleic acid samples of (b) to a DNA microarray; (d) performing hierarchical clustering analysis on data obtained from the hybridization, wherein the clustering analysis identifies differentially expressed genes that classify the plasma cells and B cells according to their developmental stages; (e) isolating multiple myeloma plasma cells from individuals with multiple myeloma; (f) isolating nucleic acid samples from the multiple myeloma plasma cells; (g) hybridizing nucleic acid samples of (f) to a DNA microarray; (h) performing hierarchical clustering analysis on data obtained from (g); and (i) comparing the analysis in (h) to that in (d) to classify the multiple myeloma plasma cells according to the developmental stages of normal B and plasma cells.
 12. The method of claim 11, wherein the genes differentially expressed during plasma cell differentiation are listed in Table
 14. 13. The method of claim 11, wherein the genes differentially expressed during early-stage differentiation of plasma cells are listed in Table
 15. 14. The method of claim 11, wherein the genes differentially expressed during late-stage differentiation of plasma cells are listed in Table
 16. 15. The method of claim 11, wherein the plasma cells and the B cells individually are isolated from tonsil, bone marrow, mucosal tissue, lymph node, or peripheral blood.
 16. A method for treating a multiple myeloma in an individual, comprising the step of: increasing expression of one or more genes in Table 4; or inhibiting expression of one or more genes in Table 5 and Table 9; or a combination thereof, thereby altering differential expression of the multiple myeloma genes to treat the individual. 